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QUANTITATION OF GROUP A ROTAVIRUS BY REAL TIME POLYMERASE
CHAIN REACTION IN CHILDREN WITH VARYING SEVERITY OF
GASTROENTERITIS
DISSERTATION SUBMITTED AS PART OF FULFILMENT FOR THE M.D.
(BRANCH-IV MICROBIOLOGY) DEGREE EXAMINATION OF THE TAMILNADU
DR.M.G.R.MEDICAL UNIVERSITY, TO BE HELD IN APRIL 2014
INDEX
S. No Section Page Number
1 Introduction 1
2 Aim and Objectives 4
3 Justification of the Study 5
4 Review of Literature 6
5 Materials and Methods 44
6 Results 54
7 Discussion 72
8 Conclusion 76
9 Appendix 77
10 Bibliography 88
11 Annexure 99
CERTIFICATE
This is to certify that the dissertation entitled, ‘Quantitation of group A rotavirus by
real time polymerase chain reaction in children with varying severity of
gastroenteritis’ is the bonafide work of Dr. Susmitha Karunasree Perumalla towards
the M.D (Branch - IV Microbiology) Degree examination of the Tamil Nadu
Dr.M.G.R Medical University, to be conducted in April 2014.
Gagandeep Kang V. Balaji
Professor and Head Professor and Head
Division of Gastrointestinal Sciences Department of Clinical Microbiology
Christian Medical College Christian Medical College
Vellore- 632004 Vellore- 632004
ACKNOWLEDGEMENT
My Lord Jesus Christ, whose unfailing love keeps me going enabled me to see this day.
I am blessed with a good guide Dr. Gagandeep Kang , with a matchless aspiration for
high standards and perfection in research and at the same time endowed with a load of
patience and understanding. She made sure I had help at every stage of this dissertation
and a proper orientation to this exercise. Thankyou Ma’am .
A heartfelt thanks to:
All the children in the study and their parents for their willingness to contribute to a good
cause.
The Institutional Review Board for the research grant.
My co investigators Dr. Sudhir Babji and the Heads of the units of the Department of
Child Health, Dr. Anna Simon, Dr. Leni Mathew, Dr. Kala, Dr. Indira Agarwal who
helped and encouraged the study.
Dr. V.Balaji, Head of the department of Clinical Microbiology for his constant concern
and encouragement.
Dr. Mary S Mathews for being a constant source of peace and support.
Dr. Ira Praharaj and Dr. Visali Jayaseelan for their affection, encouragement and help.
Mr.Rajesh, Mr. Robinson, Mr.Robin, Dr.Vipin and Ms. Yamini from the Wellcome Trust
Laboratotory for teaching and helping me with the technical aspects.
Mrs. Pushpa, Ms. Nandhini, Mr. Alfred, Mr. Dasthagir, Ms. Lakshmi, and Ms.Kalai for
their willingness at all times in helping out with the samples.
My colleagues from the postgraduate course for cheering me up at all times.
My parents and daughter for their love and prayers and all those who constantly prayed
for me and wished me well.
1
INTRODUCTION
Rotaviral gastroenteritis is one of the leading causes of mortality and morbidity in
Indian children below 5 years of age. India spends about 2 to 3.4 billion rupees
annually on the treatment of these cases (1). One in approximately every 260 children
below five years of age die of rotavirus diarrhea every year (2).
Faeco oral route is the most important mode of transmission and hence improvement
in sanitation and general hygiene should ideally prevent transmission. However, even
in the developed countries, this could not be achieved. It is difficult to prevent feco-
orally transmitted diseases in developing countries without multiple preventive
measures, including vaccination. The World Health Organization (WHO) has
recommended incorporation of vaccines against rotavirus diarrhea in the national
immunization schedules of developing countries with high diarrheal mortality (3).
Though vaccines are available, they have to be in a reasonable price range to be
affordable for the poorer countries which have the majority of the mortality and severe
disease burden. To cater to this need in India, various indigenous vaccines are being
developed.
Rotavirus is a double stranded RNA virus belonging to the family Reoviridae. The
genome is segmented. The virus is a triple layered particle with outer, middle and
inner layers. Different serogroups are identified based on the antigenic specificity of
the middle layer of the virus and electrophoretic mobility of the 11 RNA segments of
the viral genome. Out of the seven different serogroups (A – G) identified, groups A,
B and C are associated with humans and group A viruses are most commonly
2
associated with severe life threatening disease worldwide (1). Among the serogroups,
there are genotypes which are designated G and P types based on the antigenic
determinants of the outer layer. Distribution of the genotypes varies from place to
place and more than one genotype may exist in a given geographical region.
Gastroenteritis with its causes, pathophysiology and clinical features is a well defined
entity. The choice of variables in objectively defining the severity of gastroenteritis
are varied. Defining severity objectively helps in assessment of the effect of
therapeutic and preventive intervention. In assessing severe disease, a number of
scoring systems have been developed, based on objective signs and symptoms
reported by mothers. The most widely used scoring system for clinical assessment of
severity is the 20 point Vesikari scoring system (4) with seven different components
determining if an individual has mild, moderate, severe or very severe gastroenteritis.
Rapid development of molecular techniques helped not only in detection but also in
quantitation of the virus. Virus quantitation in stool is a marker for viral replication
since gut is the primary site of viral replication. Real-time polymerase chain reaction
(RT-PCR) is a simple, very sensitive and less time consuming test in comparison to
conventional PCR assays in detecting very small amounts of nucleic acid with less
chance for cross contamination. It enables us to view the increase in the amount of
DNA as it is amplified in real time. It has been estimated that real-time PCR resulted
in 186% increase in detection of the virus as compared to electron microscopy (5).
Quantitation using real time polymerase chain reaction, has helped in studying the
associations of viral load with various aspects of pathogenesis and outcome of
infection. In a previous study on rotavirus infection and gastroenteritis, it was found
3
that children with more severe diarrhea had greater viral loads (6). Although any gene
of the virus could be amplified for quantitation, generally if the purpose is to
distinguish between related viruses, a variable region of the genome is used and if the
purpose is to quantify the amount of virus, a conserved region is used for
amplification. Among the relatively conserved viral genes, VP6 is a suitable target for
amplification and encodes the protein used for grouping rotaviruses. VP6 is a
structural protein of rotavirus which forms the middle coat of the triple layered
particle. It is highly antigenic and is employed in several commercial kits available for
detection of rotavirus through enzyme immune assays.
This study estimated the viral load in stool samples from children with gastroenteritis
in Vellore by quantitative real time reverse transcriptase PCR of the VP6 gene using
Taqman probes.
4
AIM OF THE STUDY
To study the correlation between Group A rotavirus load and severity of
gastroenteritis.
OBJECTIVES OF THE STUDY
To correlate viral load by real-time PCR in children with mild, moderate and severe
rotavirus gastroenteritis assessed by the 20 point Vesikari scoring for rotavirus
diarrhea.
Hypothesis
Clinical severity of rotavirus gastroenteritis will correlate with the amount of virus
excreted.
5
JUSTIFICATION FOR THE STUDY
The study was conducted to examine viral excretion from children with rotaviral
gastroenteritis in stool samples with defined Vesikari scores. Vaccines are being
developed indigenously and there will be a need to test them for their ability to
prevent severe rotavirus diarrhoea. In order to provide an additional capacity to test
severe disease, we intended to estimate the range of viral excretion in children with
Vesikari scores for mild (score 1-5), moderate (score 6-10), severe (score 11-15) and
if possible, very severe disease (score 16-20). With the ongoing clinical trials on
vaccines, estimation of viral load in stools excreted will be an important tool in
studying vaccine efficacy.
6
REVIEW OF LITERATURE
1. ROTAVIRUS DISEASE BURDEN
1.1 Global scenario
Globally, diarrhoea is the second leading cause of death among children under five
years of age (7,8). One of every nine deaths in this age group is because of diarrhea
(7). Worldwide statistics in 2008 reveal that approximately 4,53,000 deaths due to
diarrhea in the under five age group are because of rotavirus infection i.e. about 37
percent of all diarrheal deaths and five percent of all deaths in the <5year age group
are because of rotavirus diarrhea (2). When categorised into mild, moderate and
severe diarrhea based on the care to be given, i.e. home care, hospital/ clinic visit and
hospital admission respectively, rotavirus diarrhea has been estimated to result in
approximately 111 million episodes requiring home care, 25 million cases requiring
out-patient visits to a hospital and 2 million cases requiring hospitalization in the
under five age category (9).
By the time children reach 5 years of age, almost all of them would have an episode of
rotaviral diarrhea. One in five children will visit the out-patient clinic and one in 60
children will be admitted to a hospital (9). About 98% of rotavirus diarrheal deaths
occur in the developing countries. The five major countries contributing to more than
half of rotavirus diarrheal deaths are Ethiopia, Democratic Republic of Congo,
Nigeria, India and Pakistan (10). Nearly 95% of all children will have evidence of
prior infection (11).
7
Figure 1. Causes of death in children in the <5 year age group
1.2 Disease burden: India
An estimate of disease burden revealed that about 122,000-153,000 rotavirus diarrhea
deaths are from India (1). In other words, India contributes to over 20% of the
rotavirus diarrheal deaths globally (12). In addition, 457,000–884,000 hospital
admissions, and over 2 million out-patient consultations in children <5 years of age
occur annually in India because of rotaviral diarrhea (1). This poses a heavy economic
burden on a developing nation.
8
1.3 Economic burden
The total medical costs can be broadly divided into direct and indirect costs. Direct
costs are direct medical expenses incurred which pertain to hospitalization and
treatment. Direct non-medical costs pertain to transportation to and from the hospital,
amount spent by the family to stay with the sick child at the hospital, etc. Indirect
costs include loss of wages incurred by the parents,etc. The expenditure incurred
differs with the level of care i.e. primary, secondary or tertiary level hospitals.
Table 1. Economic burden of rotaviral diarrhea in children < 5 years of age in
Vellore, India (13)
Level of care Direct medical cost per
hospitalization
Direct non medical costs per
hospitalization
Primary Rs. 1833.28 Rs. 45.72
Secondary Rs. 4289.56 Rs. 332.46
Tertiary Rs. 3530.81 Rs. 46.20
Thus the burden of direct medical costs due to rotaviral gastroenteritis in India in
children <5 years of age ranges from Rs. 1.8 to 3.2 billion annually. The indirect costs
account for a 64 million rupees in the outpatient visit setting (1). India spends Rs.
71.93 – 126.17 per child per year for treating rotaviral gastroenteritis (1).
9
2. ROTAVIRUS: HISTORY
In 1963, Adams and Kraft, using the electron microscope described murine rotavirus
as the causative agent of epizoonotic diarrhea in infant mice (EDIM) (14). Following
this, rotaviruses were also isolated from many other animals with gastroenteritis.
In 1973, viral particles were seen by electron microscopy of biopsies from duodenal
specimens from children with gastroenteritis. They were about 70nm in diameter (15).
Thereafter, they were observed in stool samples of children with diarrhea (16–18).
Because of their morphological appearance, they were designated Rotaviruses (in
Latin where „rota‟ means „wheel‟). They were soon identified as causative agents in
gastroenteritis in children worldwide.
2.1. REOVIRIDAE FAMILY
Rotavirus belongs to Reoviridae family. The Reoviridae family comprises of nine
genera. The viruses exhibit a wide host range, which include plants, invertebrates and
vertebrate hosts. The most common genera that are important in human diseases are
Orthoreovirus, Orbivirus, Rotavirus, Coltivirus, and the Seadornavirus. Their genome
is made up of double stranded RNA surrounded by a non-enveloped capsid. The size
of the virions is approximately 60 to 80 nm and the RNA exists in 10 to 12 segments,
which can reassort giving rise to novel viruses.
10
2.2. STRUCTURE OF ROTAVIRUS
The virus is 70 nm in size excluding the spikes. Unique features of this virus are a
segmented genome and the presence of RNA dependent RNA polymerase. The
protein capsid is icosahedral in symmetry and is comprised of three layers; an outer,
intermediate and an inner layer. Spikes made of protein project from the surface of the
outer layer. With the spikes, it is about 100 nm in size. The RNA is double stranded
and exists as 11 segments. The virus is a triple layered particle (TLP). The three layers
consist of an inner layer, a middle coat and an outer capsid. These three layers enclose
the tightly packed segmented double stranded RNA along with the VP1 polymerase
and VP3 capping enzyme complexes. Each gene segment has atleast one open reading
frame and encode the structural and non structural proteins. All gene segments except
segment 11 are monocistronic. The innermost layer is a protein shell made up of 120
copies of VP2 forming an icosahedral lattice.
The middle layer consists of 780 copies of VP6. This layer exists as trimeric pillars in
an icosahedral lattice. Though it is not exposed on the viral surface, VP6 is the main
target for the majority of antibodies elicited in rotavirus infection. Its function is to
coordinate the entry into the cell through interactions with the outer proteins VP7 and
VP4. The outer most layer is a thin glycoprotein layer formed by 780 copies of VP7.
Sixty spikes made up of VP4 project from the surface of the outer layer of the virion.
Aqueous pores perforate the middle and outer layers. The structural proteins of the
outer layer, VP4 and VP7 elicit neutralizing antibodies. VP4 gets cleaved into VP8*
and VP5* which enhances cell infectivity and penetration into the host cell. VP7
mediates calcium dependant uncoating of the virus and along with VP4 (19), help in
11
translocating the double layered sub viral particle across the host cell membrane into
the cytoplasm (20).
The virus is hardy and is not easily inactivated by treatment with various organic and
inorganic chemicals like ether, fluorocarbons, and chlorine at concentrations used for
sewage effluent and potable water treatment. They survive for weeks in drinking and
recreational waters. They have the ability to retain their infectivity for several days on
inanimate surfaces under favourable conditions of humidity (21). They are inactivated
by antiseptics containing relatively higher alcohol concentrations(>40%), >20000
ppm of free chlorine or iodophores with >10000 ppm iodine and calcium chelators
(22).
Figure 2. Structure of Rotavirus
12
2.3. PATHOGENESIS
The most common route of transmission of rotavirus is the faeco-oral route. The
manifestation of clinical infection depend on the viral and host factors. The single
most important host factor affecting the outcome of infection is the age of the
individual. Thus early neonatal period is spared owing to the transplacentally acquired
maternal antibodies. Adults rarely present with life threatening diarrhea unless it is
caused by an unusual strain or with a very high infective dose.
Virus factors involve the proteins encoded by various genes. The genes that are shown
to be associated with virulence are 3, 4, 5, 9 and 10. Gene 10 encodes the non
structural protein 4 which functions as an enterotoxin. It also regulates viral
replication and calcium balance in the enterocyte environment. As compared to
bacterial diarrhea, virus induced diarrhea shows little inflammation. Once ingested,
the virus not destroyed by the stomach acidity gets attached to the small intestinal
epithelial cells. An interaction between the virus and a series of sialylated and non
sialylated receptor molecules on the host surface brings about binding of the virus to
the host cell. Studies in animal models show that intestinal villous epithelium is the
site of attachment whereas the crypt epithelium is relatively spared (23).
The pathophysiology is multi-factorial. The postulated mechanisms of pathogenesis
involve a malabsorption component resulting from damage to the absorptive intestinal
villi caused by the virus. There is also a down regulation of absorptive enzymes
produced by the enterocyte. Rotavirus causes an increase in intracellular calcium thus
disturbing the intracellular homeostasis. NSP4 plays a key role in the increase in
13
intracellular calcium ions. It causes the release of Ca2+ from the storage sites like the
endoplasmic reticulum. NSP4 from prior infected cells after binding to specific
receptors on adjacent enterocytes result in phospholipase C- inositol 1,3,5 triphosphate
mediated cascade of events ultimately causing an increase in intracellular Ca2+.
NSP4 can directly act on crypt cells or directly stimulate enteric nervous system,
which increases Ca2+ in the cells. When NSP4 acts directly on the crypt cell, there is
activation of Cl- transporter contributing to secretory diarrhea because there is a
concomitant increase in water secretion. Microvillar cytoskeletal made up of Ca2+
sensitive F-actin, villin and tubulin proteins undergoes disruption. NSP4 also acts on
the tight junctions, which maintain epithelial barrier decreasing the intracellular
resistance and cause paracellular leakage. The degree of damage to the mucosa
correlates with the severity of diarrhea (24).
The other mechanism involves an alteration in Na+/K+ equilibrium as a result of
increased plasma membrane permeability. There is an increased intracellular Na+ and
a decreased intracellular K+ (25). This imbalance may cause decreased NaCl
absorption and solute absorption, which takes place alongside Na+ and hence results
in water secretion into the lumen of the gut.
Sodium glucose transport protein 1 (SGLT1) which is responsible for sodium
reabsorption by the enterocytes is competitively inhibited by NSP4 (26). The enteric
nervous system is situated immediately beneath the villous epithelium receives stimuli
from the damaged cells. Also the prostaglandins and the chemokines released during
epithelial damage stimulate the enteric nervous system which in turn trigger the crypt
cells to pour out the secretions into the gut lumen.
14
Immunofluorescent staining and light microscopic examination of duodenal biopsy
specimens from children presenting with severe diarrhea showed patchy rotavirus
antigen distribution over the villous epithelium and short blunt villi with crypt
hypertrophy respectively (24,27).
.
Figure 3. Pathogenesis of rotavirus diarrhea
15
2.4. IMMUNITY IN ROTAVIRAL INFECTIONS
Protective immunity is mediated by both the cellular and humoral immune system.
Serological response to the first infection is believed to be homotypic i.e. directed
towards specific viral proteins. The subsequent infections elicit a heterotypic
serological response which is broader (28). In the case of most immunocompromised
patients, severe diarrhea is rarely a consequence of natural infection but viral shedding
takes place over a prolonged duration.
Severe diarrhea is however seen in severely immunocompromised individuals (i.e.
congenital immunodeficiency states, solid organ or bone marrow transplant patients)
(29). Studies have shown that in children, soon after natural infection, rotavirus
specific serum IgA correlates with intestinal IgA levels and it can be used as a
correlate for protection, and in vaccine trials, circulating IgA antibody levels in serum
have been considered the best marker for vaccine take (30).
Rotavirus antigenemia was observed in children with rotavirus diarrhea and this
showed correlation with viral load detected in the stool samples. This however did not
translate into any increase in extra intestinal manifestations of the infection (31).
Viremia was seen in 90% of antigenemic children in a study. The presence of viremia
can be explanatory of the extra intestinal manifestations of the infection (32).
16
3. CLINICAL FEATURES
The clinical spectrum is varied and ranges from asymptomatic subclinical infection to
severe life threatening diarrhea resulting in death. The incubation period lasts for 1 – 3
days and symptoms that follow may be of abrupt onset. There are however no striking
clinical or epidemiological features which can differentiate a child with rotaviral
diarrhea from a child with diarrhea attributable to any other etiology.
Infections in neonates may be asymptomatic because of the presence of circulating
maternal antibodies (33,34). In addition, the immature alimentary tract and also the
phenomeneon of reassortment occurring in the rotavirus genome giving rise to unique
strains with a possibly different virulence mechanisms may be responsible for the
asymptomatic nature of most of the neonatal infections. It was also noticed that the
first episodes of rotaviral infection, past the neonatal period (around 3 to 24 months of
age) may present with more vomiting than watery diarrhea, along with fever. Even
beyond this period, vomiting frequently precedes diarrheal onset and may persist for 2
to 3 days. About a third of patients present with fever. Loose and watery stools are
typical leading to life-threatening dehydration. The dehydration associated with this
virus is comparatively more severe than that associated with other common gut
pathogens(35,36). Diarrhea may continue for 4 to 5 days. Dehydration and the
resulting electrolyte imbalance leads to cardiovascular failure which is the most
common cause of death (37). Virus can be detected in infected stools using antigenic
tests for about 4 to 10 days after the onset of symptoms. Using more sensitive
methods like reverse transcriptase PCR, the detection can extend to 57 days though
17
the child may not be shedding infectious particles at this point (38). Usually there are
no RBC or leukocytes in the stool (39).
In children with immunocompromised states, rotavirus infection manifests as chronic
diarrhea. Neurological symptoms and the subsequent detection of rotavirus in cerebro
spinal fluid of children have been reported. Various other conditions like aseptic
meningitis, otitis media and respiratory illnesses which are extra intestinal infections
have also been reported. Detection of rotavirus antigenemia and viremia in children
with gastroenteritis is in support of extra intestinal manifestations. The virus has also
been seen in a variety of conditions like sudden infant death syndrome,
intussusception and necrotizing enterocolitis, but these findings may be co-incidental
and not causal (40,41).
4. EPIDEMIOLOGY
Six to twelve months of age is the most vulnerable period for severe gastroenteritis
(42). The age at which severe gastroenteritis usually happens is proportional to the
waning of maternally derived antibodies, the maturation of the child‟s GI tract and the
active acquisition of immunity due to natural infection (43). Though the rate of
occurrence of rotaviral infection is similar in both developed and developing
countries, mortality is higher in the latter. Malnutrition, lack of access to timely
medical care, coinfections with other intestinal pathogens may be some of the
contributing factors (44). The hardy nature of the virus, its relatively high
concentrations of 1011
particles/mL in stool (45) and low minimum infective dose of
10 focus forming units (46) are also responsible for the high incidence rates. The peak
incidence in temperate regions is in the cooler months (47). Cooler and drier months
18
are preferred in the tropical areas though there is no clear demarcation in the seasonal
appearance in the tropics. The drier climate may be preferred for its transmission
because of lower relative humidity which inactivates the virus (21).
Figure 4. Mortality due to rotavirus in the <5 year age group
19
4.1 SEROTYPES/ GENOTYPES
There is a high level of antigenic and genomic variability in circulating human
rotaviruses. Both antigenic determinants and genomic information have been used as
the basis for classification. Serogroup is the broadest unit of classification, and is
based on the VP6 protein. Seven groups (A-G) are identified, among which group A
rotaviruses are found to be the commonest, causing life threatening diarrhea in
children all over the world. The determination of serogroups and these subgroups was
carried out by using hyperimmunized serum from animals (32). The VP6 antigen can
be detected by serological tests like immunofluorescence, enzyme immunoassays and
methods like immune electron microscopy. Genetic reassortment can take place
between rotaviruses of the same group but does not occur among different serogroups.
Groups A, B, and C rotaviruses are seen in humans and animals. Groups D, E, F, and
G have been reported only in animals so far. Group A rotaviruses are implicated in
endemic diarrhea of children. Group B and group C infect all age groups. The adult
diarrhea rotavirus (ADRV) belongs to Group B and it was responsible for massive
outbreaks of adult gastroenteritis in China (49). Group C is associated with mild
diarrhea in both adults and children (50,51).
Serogroup A is further divided into various subgroups. They are subgroups I, II, I+II,
and non-I non-II based on monoclonal antibody recognition of VP6 antigenic
determinants (52). The initial serological classification within group Agave a binomial
nomenclature comprising of a „G‟ serotype and a „P‟ serotype for each virus strain.
Thetwo proteins, VP7 and VP4, of the outer layer and the spikes, respectively, induce
antibody responses which are neutralizing and the genetic variability involved in
20
encoding them is the basis for G and P type classification (53). Around 14 G serotypes
(G1 to G14) and atleast 20 P serotypes (P[1] to P[20]) are identified so far and of
these, 10 G types and about 5 P types are found in humans infected with rotaviruses
(53).
In the case of G type, there is a one to one correspondence between the protein and
gene, such that serotypes, based on monoclonal antibodies, and genotypes have the
same nomenclature. This is however not the case with P serotypes where there are a
lot of cross reactions within the P serotypes, and a P serotype can include more than a
single genotype.
Rotavirus strains may exhibit a degree of confinement to a particular geographic
region or variations with climatic conditions. Factors like genetic reassortment
between animal and human strains, antigenic drift and introduction of animal
rotaviruses into the circulating pool of human strains ensure a continuous
phenomenon of genetic diversity. Hence surveillance becomes imperative in
determining whether new strains are emerging (54). Several G and P types may be
circulating in a given diarrheal season. Though there are dominant G and P types with
geographical confinement, they may be replaced by other strains during a particular
rotaviral gastroenteritis season (55). Till 1990, the four most common combinations of
G and P types seen were G1P[8], G2P[4], G3P[8] and G4P[8]. With increased strain
surveillance, new GP combinations are being found. Currently, the most commonly
occurring G serotypes are G1 to G4 and G9. The commonest P genotypes are P[4],
P[6] and P[8] and their corresponding serotypes are 1B, 2A and 1A respectively (56).
The five most prevalent GP combinations are G1P[8], G2P[4], G3P[8], G4P[8] and
21
G9P[8]. Uncommon strains are also found. Regional serotypes of importance are
G8P[6] in Africa and G5P[8] in Brazil (48). The G9 strains were first identified in
children with gastroenteritis in Philadelphia. There are some reports of increased
severity of gastroenteritis in Latin American countries (57), and children <6 years
showed increased risk of infection by the new strain (58). Currently G9P8 strains are
one of the most commonly circulating strains worldwide. Children can have multiple
episodes of diarrhea caused by different G and P types. The protective efficacy of the
prior natural rotavirus infection over the subsequent infections ranged from 46% to
100%. Generally it is thought that the initial infections conferred homotypic protection
which later broadened to a heterotypic protection. A more recent study conducted by
Kang et al, where 373 children were followed up from birth for a three year period
showed that although there was protection, there was no evidence of homotypic
protection alone offered by the initial infections (59).
4.2 GENOTYPES IN INDIA
Strains belonging to different genotypes are reported from different parts of the
country. G1, G2, G4, G9 and G12 are among the commonest VP7 genotypes and P[4],
P[6], P[8] and P[11] are the common P types reported from all over India. With the
introduction of molecular biology based typing methods, detection of so far
untypeable strains is being done and thus the unusual strains are increasingly being
detected. Many of them are believed to be of animal origin or reassortants between
animal and human strains because of their identity with the corresponding genes in the
rotaviruses infecting animals.
22
G6 strain and G8 strain showed more than 95% identity with VP7 gene of the bovine
rotavirus strains. The G6 strain was described from Pune (60) and G8 from Vellore
and Mysore (61,62). The VP7 gene of G3P[8] shares 100% identity with the VP7 of
simian rotaviruses and the P[8] component has 99% identity with the P[8] of human
rotaviruses. This was described among the tribal residents of Western India (63).
G9P[19] is a porcine–human reassortant and is described from Manipur (64). Another
genotype which is a bovine – human reassortant is the G10P[11] genotype described
from Vellore (65). G12 strains which were first identified in Philippines were
increasingly reported from India. The G12 genotype is seen in combination with many
P types. Among hospitalized children, data from Vellore during the period 2002- 2005
reveal that the most predominant VP7 types were G1 followed by G9 and then G2
(65). A reversal of the above order was observed in studies conducted in the same
region during 2005-2007 where G2 was the most common G type followed by G9 and
then G1. Other genotypes like G3 and G4 which are among the commonest types
found worldwide were not reported.
23
Figure 5. Global distribution of G and P types from five continents between 1989
and 2004 (Rev.Med. Virol. 2005)
24
5. LABORATORY DIAGNOSIS OF ROTAVIRUS
The different techniques to detect rotavirus in the laboratory are i) Virus isolation
using cell culture techniques, ii) Electron microscopy, iii Serological methods to
detect the antigen, including Enzyme immunoassay (EIA), Latex agglutination,
Immunochromatography and iv) Nucleic acid detection.
5.1. Cell culture techniques for virus isolation
Virus isolation can be performed on rhesus monkey kidney cell lines (MA104, LLC-
MK2 cell line), African green monkey kidney cell lines (BSC1, CV1) and Madin
Darby bovine kidney cell line. After an incubation period of 18 hours, the cell line is
examined for cytopathic effect.
5.2. Electron Microscopy
It demands well trained personnel with technical expertise and is a very expensive
instrument. Moreover, the distinction between the various serogroups cannot be made
based on electron microscopy. A minimum number of viral particles for detection by
electron microscopy is 107 viral particles/ml of stool (17).
5.3. Serological tests for Antigen detection
The most common methods in serological detection employ antibodies specific for
rotavirus antigens. The captured antigen is detected in a colorimetric reaction where a
second rotavirus specific antibody attached to a detector enzyme is employed. The
result in terms of optical density values is recorded by the standard plate reader.
Three commercial kits are recommended for surveillance in the manual on rotavirus
detection and characterization by the WHO are PremierTM
Rotaclone (Meridian
25
Biosciences; Cincinnati), ProSpecT™ (Oxoid) and RIDASCREEN® (R-biopharm,
Darmstadt, Germany).
Table 2. Performance of commercially available EIA kits for rotavirus detection
Study ELISA kit Reference test Sensitivity Specificity
R Gautam et
al., 2013(66)
Rotaclone
ProSpecT
Ridascreen
Reverse
transcription
PCR
76.8%, 75%
and 82.1%
respectively
100%
Bodo RE et al.,
2001(67)
1.Ridascreen
2.Pathfinder
rotavirus
Electron
microscopy
100% 99.73% and
79.1%
respectively
Morinet F et
al.,1984(68)
Rotazyme
Enzygnost
-Relative
sensitivity-
89% and 98%
respectively
---
JL Cromien et
al., 1987(69)
Rotazyme EIA
Rotazyme II
EIA on
MA104 cell
culture
supernatants
using the same
kits
100% 100% and 90%
respectively
Dennehy PH et
al.,1988(70)
1.Rotaclone
2.Pathfinder
rotavirus
RNA-PAGE 100% 100% and 98%
respectively
5.4. Latex agglutination methods
Latex particles are coated with the antibody specific for rotavirus antigen and if the
antigen is present in the fecal specimen, there would be agglutination of the latex
particles. This can be performed on a glass slide and visualised by the unaided eye or
by use of a hand lens. It was thought that this test was faster and cost effective and
could be performed in the paediatric wards. Initial evaluation of Rotalex, a latex
agglutination kit by Orion diagnostics, Helsinki Finland, showed low sensitivity and
specificity when compared to enzyme immunoassay and electron microscopy (71).
26
5.5. Immunochromatography
In resource poor settings, immunochromatography may help overcome the barriers in
detection and studying the epidemiology of rotavirus diarrhea. Though the sensitivity
and the specificity obtained using some kits was comparable to that of enzyme
immunoassay, latex agglutination in some studies(72–74), others have reported
discordant results (75,76).
5.6. Nucleic acid detection methods
5.6.1. RNA Polyacrylamide gel electrophoresis
Large amount of viral particles are shed from stools in children with gastroenteritis
and the nuclear segments can be visualised after extracting from the virus and running
it electrophoretically on polyacrylamide gel after staining with either silver nitrate or
ethidium bromide. Groups A, B and C are the human rotavirus groups and these have
distinct bands corresponding to gene segment distribution after electrophoresis. Since
this method detects both the presence of rotavirus and its serogroup, polyacrylamide
gel electrophoresis (PAGE), has been used for Group A rotavirus surveillance.
The RNA which is extracted from Group A rotavirus can be categorised into four
classes based on the size; large, medium, small and smallest segments. They also
occur in „short‟ and „long‟ electropherotypes. This procedure is labour intensive and
needs a trained technologist. The sample is considered positive for Group A rotavirus
if the 11 segments of double stranded RNA are visible and correspond to the group A
rotavirus control.
27
Figure 6. PAGE gel showing differences in segment migration configuration of
Group A, B and C Rotavirus
5.6.2. Reverse transcription PCR
Reverse transcriptase PCR helps in improved identification of viral shedding when
compared to enzyme immunoassay, latex agglutination or immunochromatography
tests (77,78). Viral nucleic acid can be detected 2 to 7 days longer than when detected
using the enzyme immunoassay (77). RT-PCR can detect and identify the G and P
types by using primers which are specific for the VP7 and VP4 genes. The PCR
products which are obtained are genotype specific and can be detected after running
electrophoretically on agarose gel. Reverse transcriptase PCR takes place in three
28
important steps i.e., denaturation of double stranded RNA, reverse transcription of
dsRNA to form the complementary DNA and amplification of cDNA. Denaturation of
dsRNA is brought about by heating to separate the two strands. Complementary
primers are added along with reverse transcriptase to form the cDNA. DNA
polymerase enzyme extends the strand and synthesizes the new cDNA. The newly
synthesized cDNA in each cycle undergoes denaturation, annealing and extension
steps and gets amplified.
The genotyping methods employ a semi- nested RT-PCR where the viral RNA is
reverse transcribed and amplified in the presence of consensus primers for genes
encoding the VP7 and VP4 proteins (79–82). DNA obtained in the first amplification
cycle functions as a template for the second PCR which takes place in presence of
consensus primers and genotype specific primers. The products obtained are analysed
after agarose gel electrophoresis and depending on the size of the products on the gel,
the genotypes are determined.
Alternately the reverse transcription step can be carried out in presence of random
hexamers instead of specific primers to obtain cDNA. The advantage here is that other
enteric viruses can also be detected using specific primers for those viruses since the
random hexamers prime any RNA present in the specimen (83).
5.6.3. Real time reverse transcriptase PCR
Real time PCR helps in quantitation of rotavirus particles present in the sample. It
detects nucleic acids present in minute amounts.
29
6. REAL TIME POLYMERASE CHAIN REACTION
Post PCR analysis and quantitation following reverse transcription PCR is by gel
electrophoresis and analysis of the image. Real time PCR offers a platform where the
PCR product can be measured at each cycle in real time with precision using
fluorescent dyes/probes which emit increasing signal with increase in amplicons. The
fluorescent reporters used usually are dsDNA binding fluorescent dyes, or PCR
primers/probes attached with the dye molecules. The fluorescence change is measured
by an instrument that combines thermal cycling with fluorescence scanning ability. By
plotting fluorescence against the cycle number, the amplification plot is generated.
The entire amplification and detection occurs in a single tube eliminating the need for
post PCR manipulations.
Steps involved in real time PCR
6.1. Denaturation
High temperatures (95°C) are used to separate the two strands of the dsDNA. The
denaturation time can be increased based on the amount of GC content present in the
template.
6.2. Annealing
This is calculated based on the melting temperature (Tm) of the primers which is
usually 5°C below the Tm of the primer. Complementary sequences hybridize during
this stage.
6.3. Extension
The activity of the polymerase enzyme is best at 70-72°C. When the amplicons are
small, this step is combined with the annealing step using 60°C as the temperature.
30
6.4. Fluorescence detection systems
The most commonly used fluorescence detection systems in real time PCR are the dye
based assays and 5‟ nuclease assays.
6.4.1. Dye based chemistry
The commonly used DNA binding dye is SYBR Green I. It binds non specifically to
dsDNA which exhibits little fluorescence in the unbound state. The fluorescence
increases 1000 fold when it is bound to dsDNA. This fluorescence signal increases as
the target gets amplified. A major drawback of these DNA binding dyes is their lack
of specificity as they bind to any double stranded DNA.
6.4.2. Fluorescent Primer and Probe based Chemistries
The most common probe based chemistry is TaqMan chemistry. Taq polymerase is
thermostable and has 5‟ exonuclease activity. In addition to the exonuclease property,
these assays also exhibit a phenomenon called fluorescent resonance energy transfer
(FRET). In FRET, energy from a fluorescent dye can be reduced by the presence of
another dye in close proximity called the quencher. It employs a sequence specific,
fluorescently labelled oligonucleotide probe called the TaqMan probe. It contains a
fluorescent reporter at the 5‟ end and a quencher at the 3‟ end. When the probe is
intact, FRET phenomenon is at its optimum before the PCR starts. Once the annealing
/ extension takes over, the probe hybridizes to the target and the 5‟ exonuclease
activity of the Taq polymerase cleaves off the reporter. The fluorescence is not
quenched as the reporter is separated from the quencher and it increases with each
amplification cycle.
31
6.4.2.1. Types of Taqman probes
The two types of Taqman probes are the MGB and non-MGB probes. The non-MGB
probes were used initially and where TAMRA® dye was used. The annealing
temperatures of these probes had to be higher than the primers to allow cleavage to
take place and hence the probes had to be longer than the primers.
The MGB probes have a minor groove- binding molecule on the 3‟ end. A minor
groove is formed in the DNA where the probe binds and this raises the melting
temperature of the probe. Taqman MGB probes are short. Hence even a single base
mismatch has an impact on probe binding. Hence real time PCR employing Taqman
MGB probes are highly specific.
6.5. Passive reference dye
Use of passive reference dye in real time PCR helps in normalizing the fluorescence
signals that are not related to the PCR cycle and provide a stable baseline.
High specificity and high signal to noise ratio are the main advantages of using
TaqMan probes. Detection of rotavirus using real time PCR is higher than that
detected using reverse transcriptase PCR and the time is half that required for
conventional PCR. Real Time PCR when initially performed on rotavirus, amplified a
highly conserved region in the non structural protein 3 which is 87- bp long (84).
In addition to the need for understanding the biology of replication, there is a need for
viral load estimation to attribute a causal relationship in patients with diarrhoea
because some healthy individuals also can be positive for rotavirus when very
sensitive nucleic acid detection methods are employed.
32
Figure 7. Diagrammatic representation of the steps in real-time PCR thermal
cycling process
6.6. Amplification curve
Amplification curve in a PCR run can be divided into three important phases.
6.6.1. Exponential phase
A doubling of the reaction products happen during this phase. The reaction runs at
100% efficiency because all of the reagents are available. Hence double the
amplicons accumulate at the end of the cycle.
33
6.6.2. Linear phase
As the reaction progresses, the reagents get consumed whenever there is doubling of
the amplicons. At this point, the reaction starts to slow down and there is no more
exponential increase seen in the amplicons.
6.6.3. Plateau phase
The reaction stops in this phase and no more amplicons will be made. The PCR
products may even degrade if left long enough. Each sample has its own plateau phase
depending on the reaction kinetics of the sample.
6.7. Real time PCR analysis
Figure 8. Real time PCR plot
34
6.7.1. Baseline
It is the signal level in the initial cycles of the real time PCR where there is little or no
change in fluorescent signal. If low level signal can be detected at this point, it is
considered as the background „noise‟. Baseline should be determined carefully so that
enough cycles contributing to background noise are eliminated and at the same time,
care should be taken to see that no amplification signal is missed.
6.7.2. Threshold
Threshold is the level which separates background noise from relevant real
amplification. It can be set manually or automatically. In the automatic mode, the
machine sets it at 10 times the standard deviation of the fluorescence value of the
baseline.
6.7.3. Threshold cycle (Ct)
It is the cycle number at which the fluorescent signal of the reaction crosses the
threshold. Ct value is inversely related to the starting amount of the target.
6.7.4. Standard curve
A known template is serially diluted and a standard curve is constructed to determine
the initial amount of the target template. The log of each concentration on the x-axis is
plotted against the Ct value for that concentration. Using the standard curve, the
performance of the reaction and the various reaction parameters can be deduced. The
concentrations of the known template should be chosen in such a way that they
encompass the expected concentration range of the target templates used in the real
time PCR.
35
6.7.5. Correlation coefficient (R2)
It determines how well the data fits the standard curve. It is a reflection of the linearity
of the standard curve.
6.7.6. Slope of the standard curve
The slope of the log linear phase of amplification reaction is a measure of efficiency
of the reaction. A reaction efficiency of 100% corresponds to a slope of -3.32.
6.7.7. Efficiency
An ideal efficiency of 100% means that the template doubles after each thermal cycle
during exponential amplification. Length, secondary structure and GC content of the
amplicon are the experimental factors that can influence efficiency. Using non optimal
reagents, presence of PCR inhibitors in the reagents are a few of the reaction factors
that contribute to altered efficiencies. A reaction efficiency between 95% and 105% is
considered acceptable.
6.7.8. Dynamic range
This is the range over which an increase in starting material concentration results in a
corresponding increase in amplification product.
36
7. TREATMENT
Treatment mainly focuses on rehydration and ameliorating the effects of dehydration
caused by diarrhea. There is no specific treatment other than fluid replacement and
zinc. Low osmolality solutions are preferred over conventional formulations of oral
rehydration salts (89). Since rotaviral diarrhea is also associated with vomiting, the
extent of dehydration is much more, and oral rehydration alone may not be sufficient
in severe cases. The child may need hospitalization and intravenous rehydration. The
health care seeking in these developing countries is also less owing to social,
economic and cultural constraints. Thus vaccines hold a promising future in
restraining the mortality and morbidity due to rotavirus gastroenteritis.
However, the effectiveness of these vaccines in the poorest regions, which contribute
to majority of mortality, is still questionable due to the existence of other concomitant
infections and the lack of information on the circulating and newly emerging strains in
those geographical regions.
Some studies showed that passive immunization using hyperimmunised bovine
colostrum or chicken yolk immunoglobulin were protective against rotavirus diarrhea
(86–88). Racecadotril which is an encephalinase inhibitor acts on the enteric nervous
system mediated secretory component of rotavirus diarrhea and can be used in the
treatment of rotavirus diarrhea (89). Oral administration of certain lactobacillus
species in children with rotavirus diarrhea reduced the duration of watery diarrhea
(90). Laboratory studies using recombinant monovalent antibody fragments derived
37
from llama immunized with rotavirus showed neutralizing effect on various common
genotypes of rotavirus (91).
8. ROTAVIRUS VACCINES
Studies conducted on the natural history of rotavirus infections showed that the initial
infections after the neonatal period were symptomatic but conferred protection on the
subsequent infections (33,92,93). These findings provided the necessary scientific
rationale that this immunity could be imparted using live oral vaccines. It was also
seen that vaccines of low immunogenicity showed high efficacy in field trials. Hence
conducting clinical trials on a large scale may be the only secure means to estimate the
effectiveness of a vaccine (94,95).
The use of vaccines should ideally be a component of a comprehensive strategy
targeted to control diarrheal diseases. The other components should include
improvement in general hygiene and sanitation, zinc supplementation, administration
of oral rehydration solution and better management of cases (96). Efforts to
manufacture a vaccine against rotavirus started in the1980s. In 1983,the first trial with
a candidate oral vaccine derived from RIT4237strain, which is a bovine rotavirus
strain was carried out. Its results showed four basic principles regarding live oral
rotaviral vaccines. 1. They can shield children against severe diarrhea. 2. Protection
was more against severe gastroenteritis as compared to milder episodes. 3. Animal
strains can protect individuals from infections caused by human strains. 4. The
antibody levels did not determine the effectiveness of the vaccine. The RIT vaccine
developed by Vesikari did not show consistent outcome in clinical trials in developing
38
countries and was abandoned. After 15 years, the first vaccine RotashieldTM
(Wyeth-
Lederle, Pearl River, NY, USA) was licensed in the United States in August 1998. It
was developed at the National Institute of Health and was a rhesus derived tetravalent
reassortant vaccine (97,98).
Nine months after administering it to well over 60000 children, it was withdrawn from
the market because of several cases of intussusception following its administration
(99). The risk was assessed to be 1 in 10,000 vaccine recipients (100). Intussusception
was seen more in the „catch-up‟ group who were older than 90 days of age. Since the
risk of natural intussusception is lower in the first 3 months of life and hence
subsequent vaccines targeted this age group for clinical trials.
Two vaccines which are currently widely available are Rotarix®
from
GlaxoSmithKline Biologicals, Rixenstart, Belgium and Rotateq®
from Merck & Co.
Inc., West Point, PA, USA. Both are live attenuated oral vaccines. Rotarix is a
monovalent vaccine from a G1P[8] strain isolated from a case of gastroenteritis in an
infant which was subjected to serial passages in tissue culture for attenuation.
RIX4414 was the resulting strain and it is propagated in Vero cell lines. It is
administered as two doses; the first after six weeks of age and the second before 24
weeks of age. Severe combined immune deficiency syndrome is a contra indication
(101,102) because of the danger of prolonged shedding.These vaccines can be
administered along with the routine childhood vaccinations.
The pentavalent vaccine is a human- bovine reassortant vaccine. Its origins are from
human and bovine parent strains where five reassortants express either one of the four
VP7 proteins (G1, G2, G3 or G4) belonging to human strains and P7[5] from the
39
parent bovine strain or P1A[8] which is a VP4 protein from a human strain and and
G6 protein from the parent bovine strain. All the five reassortants are finally
propagated in Vero cell lines employing standard techniques. Three doses of
pentavalent vaccine are given at 2,4 and 6 months of age. During the first week after
administration of any of the rotavirus vaccines, the child has to be carefully watched
for any episodes of severe crying, vomiting, irritability, blood in stools, which may be
indicative of intussusception.
8.1. EFFICACY OF THE VACCINES
Rotarix and Rotateq vaccines showed an efficacy of 80% – 90% against severe
rotaviral gastroenteritis in WHO regions with very low or low child and adult
mortality rates, but 40% - 60% efficacy was seen in WHO regions with high child
and very high adult mortality (103,104). In Asian and African countries, efficacy is
low but there is a substantial public health impact because of the high burden of
disease, since these countries account for almost 85% of rotaviral diarrheal deaths
worldwide. A great diversity in existing strains, and occurrence of mixed infections
and the ongoing reassortment between the human and animal strains have so far not
posed a challenge to the vaccines‟ ability to offer cross protection.
8.2 Other vaccines
The Lanzhou strain used was isolated from a lamb with diarrhea and was grown on
cell lines of primary calf kidney. It was licensed as a vaccine in China. Not much data
is available on the safety, immunogenicity and efficacy of this vaccine (105).
40
The Rotavac vaccine is monovalent, based on the 116E strain of rotavirus which was
recovered from asymptomatic infections in neonatal units in New Delhi. This strain
was shown to offer protection against severe diarrhea (92). It was characterized at
AIIMS Delhi as G9P[11] human – bovine reassortant, with VP4 of bovine origin and
the rest of the segments of human origin (80). The vaccine completed the first two
phases of clinical trials successfully and interim reports from the phase III trials from
three different centres in India ie. NewDelhi, Pune and Vellore showed good results.
This vaccine will be available at a low price if approved for licensure.
9. CLINICAL SCORING OF GASTROENTERITIS
Early vaccine studies revealed that the vaccines did not protect against all severities of
diarrhea equally and that a vaccine should be able to protect against severe clinical
outcome. There were no clear definitions or cut offs for measuring severity. Different
descriptions and definitions were used in different studies to measure severity.
To measure the vaccines‟ ability to cause a reduction in severity of diarrhea,
numerical scores can be given to most important clinical symptoms in diarrhea.
A 0-9 point scoring system was put forth by Hjelt et al which took four clinical
parameters into consideration (106). They are duration of diarrhea, number of
episodes of diarrhea in a 24 hour period, duration of vomiting and fever. Flores et al
added degree of dehydration and treatment as additional parameters and brought forth
a 0-14 point scoring system (107).
Thus different vaccine trials were evaluated by a different scoring system eg. Scoring
system devised by Duffy et al 1986, Gotheforset al 1989, Clark etal 1988, Vesikariet
41
al 1984 (4,108–110). Two of these scoring systems, the Clark scoring system and the
Vesikari scoring system have been routinely used in vaccine trials. The Clark scoring
system does not assess the degree of dehydration. There have been discrepancies
between the various scoring systems in assessing the clinical severity even when they
were compared in the same clinical trial (111). One of the important components to be
assessed when comparing the different scoring systems is their ability to detect severe
diarrhea. Vesikari scoring system is considered the best scoring system for
gastroenteritis in rotaviral clinical trials (112) with relatively standardised endpoints.
9.1 Parameters and Scoring in the Vesikari scoring system
It is a 0-20 point numerical scoring system based on the clinical features with which
the child presents to the health care facility and the distribution of clinical history into
the the respective categories of the scoring system (4). According to theVesikari
scoring system, a score below 5 is considered „mild‟, between 6 to 10 is „moderate‟,
between 11- 15 is „severe‟ and above 16 is considered „very severe‟ gastroenteritis.
In children below 6 months of age, any alteration in number or stool consistency
which the mother felt was diarrhea was considered diarrhea. Atleast one day of
diarrhea preceeded and followed by two or more diarrhea free days was considered an
episode of diarrhea (113). The episode ends on the day the child starts to pass normal
stools.
42
Components of the scoring system
10.1.1. Diarrhea
The highest number of times the child passes stools is captured in the record and
scored accordingly.
10.1.2. Vomiting
The highest number of times the child vomits in a 24-hour period is captured and
scored accordingly.
10.1.3. Temperature
The highest temperature in a 24-hour period is taken. Rectal temperature is ideal.
Axillary, oral or otic temperatures can also be taken.
10.1.4. Duration of diarrhea
The total number of days from the beginning of the diarrheal episode till the child
turns symptom free.
10.1.5. Duration of Vomiting
The total number of days from the beginning of vomiting episodes till the child is
emesis free. This is calculated in a manner similar to diarrhea duration.
10.1.6. Dehydration
The degree of dehydration is calculated using four parameters. They are, appearance
of the eyes, general condition of the child (irritable, restless, lethargic, unconscious),
thirst level and skin turgor. This can be done per the physician‟s assessment or using
the WHO Integrated Management of Childhood Illnesses dehydration treatment
criteria..
43
10.1.7. Treatment
Hospitalization is more of concern than rehydration according to the scoring system
because in some of the developing countries IV rehydration may be administered even
without admitting the child to the hospital. Hence hospitalization is given a score of 2
and rehydration (IV or oral rehydration) is given a score of 1.
Table 5. Vesikari scoring system
0 points 1 point 2 points 3 points
Diarrhea duration (days) 0 1 – 4 5 ≥ 6
Maximal number of
diarrheal stools per 24-h
period
0 1 – 3 4 – 5 ≥ 6
Vomiting duration (days) 0 1 2 ≥ 3
Maximal number of
vomiting episodes per 24-
h period
0 1 2 – 4 ≥ 5
Maximal recorded
temperature, (fever)
Celsius scale
<37 37.1 - 38.4 38.5 - 38.9 ≥ 39.0
Degree of dehydration None Some Severe
Treatment None Rehydration Hospitalization
44
MATERIALS AND METHODS
Study design
This was an observational study conducted at the Wellcome Trust Research
Laboratory, Christian Medical College, Vellore in collaboration with the different
units of Child Health Department. The institution is a 2400 bedded tertiary care centre
with several paediatric wards that offer both general and specialist care to children.
The institution also runs a separate emergency department for paediatric age group
patients. The Wellcome Trust Laboratory is involved in studies on paediatric
diarrhoea. It is the World Health Organisation Rotavirus Reference Laboratory for the
South East Asian Region.
Inclusion criteria
Children below 5 years of age presenting with diarrhea to the Paediatrics department.
Study duration
The study was conducted over a period of 15 months from June 2012 to August 2013
after obtaining approval from the Institutional Review Board and Ethics Committee.
45
Study samples
Faecal specimens from children below 5 years of age were collected. A total of 150
positive samples was aimed for with 50 samples in each of the three clinical
categories, i.e., mild, moderate and severe. The sample size was calculated based on
the feasibility of the study as the outcome was not predictable. Vesikari scoring
system was employed to score severity of diarrhea in the study children. The majority
of the samples were taken from the studies being conducted on rotavirus strain
surveillance at the Wellcome Trust Research Laboratory. The rest of the samples were
collected from the in-patient and out-patient wards and the emergency department of
Child Health after obtaining the necessary consent from the parent/ guardian.
Collection, Transport and Storage
Faecal specimens which are collected as part of the Indian National Rotavirus Strain
Surveillance program are screened for at the Wellcome Trust Research Laboratory
routinely for rotavirus using the Rotaclone ELISA kit to detect VP6. These samples
are collected by the parent or nurse, kept in the ward refrigerator and handed over to
the study staff for transport to the laboratory. Parents were informed about the study,
and after the consent was obtained, a clinical assessment was performed by a nurse
using the components on the modified Vesikari Scoring system and the appropriate
score was attributed to that particular sample. Passage of three or more loose or
watery stools in a 24 hour period was considered diarrhea.
If the sample was received in the laboratory too late for the ELISA to be performed on
the same day, the specimens were stored at 4°C for ELISA to be done on the
46
subsequent day. All the specimens were aliquoted into vials and stored at -70°C for
further characterization. Rotavirus positive stool samples after ELISA were taken for
the current study and were subjected to RNA extraction, cDNA conversion and real-
time polymerase chain reaction.
Since most of the samples thus obtained were from the in-patient wards and children
with moderate to severe diarrhea usually got admitted, children from the out-patient
clinic and emergeny department who would not need admission to the wards were
also recruited into the study. Consent was obtained by the field nurse/staff or the
principal investigator from the parent/ guardian after providing information about the
study. The process employed was similar to that of the samples collected for strain
surveillance.
47
STUDY ALGORITHM
Specimens transported to the laboratory
Test specimens by Rotaclone EIA
Positive
Aliquot and store at -70 C, discard negatives
Thaw when needed for RNA extraction and reverse transcription
Real time PCR using Taqman probes
48
ENZYMEIMMUNOASSAY FOR ANTIGEN DETECTION FROM FECAL
SPECIMENS
Figure 9. Rotaclone ELISA kit
Premier Rotaclone®
kit was used for antigen detection in stool fecal specimens by
ELISA. The microtitre wells that are provided in the kit are coated with murine
monoclonal antibody against the protein encoded by the 6th
rotaviral gene (VP6). The
same monoclonal antibody conjugated to horse radish peroxidise is used in the
detector system. The results of the test were read using a spectrophotometer at 450nm.
The samples were considered positive when the A450 was > 0.150. The procedure
described in the Standard Operating Procedure and kit manual was strictly adhered to
while performing the ELISA. Personal protective equipment and a biological safety
cabinet were used for all sample handling.A 10% faecal suspension made using the
diluent provided in the kit was used for EIA (see Appendix for details).
49
RNA EXTRACTION BY QIAGEN KIT METHOD
QIA amp Viral RNA Mini Kit is away to extract and purify viral RNA for use in
amplification techniques. The kit uses silica gel based membranes which ensure
recovery of pure and intact RNA without the use of any phenol or chloroform
extraction or alcohol precipitation which may interfere with PCR. The silica gel based
membrane has selective binding capacity and its combination with microspin helps in
extraction from multiple samples at a time. The sample is first lysed under denaturing
Pure RNA
50
conditions. This inactivates the RNases and ensures recovery of intact RNA. Different
buffers are added to provide optimum binding of RNA to the QIAamp membrane of
the spin column provided with the kit. Contaminants are washed away using two
different wash buffers. RNA of high quality is eluted using RNase free buffer. This
can be converted to cDNA or stored at appropriate temperatures.
REVERSE TRANSCRIPTION
The RNA that was extracted using the Qiagen kit extraction method was converted to
cDNA. This was carried out in the presence of random primers and a reverse
transcriptase enzyme derived from Moloney Murine leukemia virus (Invitrogen, Life
Technologies, Carlsbad, CA).
The procedure for RNA extraction and reverse transcription are in the appendix.
ROTAVIRUS REALTIME PCR USING TaqMAN PROBES
In real-time PCR, DNA is amplified and detected using fluorescent chemistry. Dual
probes which are short oligos labelled with a fluorescent reporting dye at the 5‟end
and a fluorescence quencher at the 3‟ end are used. Both the reporter dye and the
quencher are in close proximity because of the size of the probes which are only 15 –
25 base pairs in length. Hence no or very little fluorescence is detected. Taq DNA
polymerase starts to extend the DNA strand from each primer during the cycling
process. The polymerase also has exonuclease activity and this results in cleavage of
the probe as the polymerase extends the strand downstream. The probe is degraded,
thus separating the reporter dye from the quencher.
51
With every additional cycle in amplification, there is an increase in fluorescence
emitted due to repeated cleavage of the probe. This helps monitor DNA amplification
in real time and avoids post amplification procedures like gel electrophoresis. This
also reduces the chances for cross contamination. It is a highly sensitive and specific
method of detection of double stranded DNA and enables quantitation of specific
pathogen levels. A 379-bp region from nucleotides 747 to 1126, which codes for aa
241 to 367 of the VP6 gene is amplified using the VP-F and VP6-R primers (114).
Figure 11. Standard curve
Figure 12. Amplification plot of the standard dilutions
RN
52
Interpretation of results
1. The measurement of rotavirus specific cDNA was calculated using absolute
quantitation by normalizing the Ct values with that of the internal plasmid control.
2. The threshold was determined automatically in the exponential phase which reflected
the highest amplification rate.
3. For the crossing points resulting from the amplification curves, the threshold indicated
the relation between the cycle number and the log concentration of cDNA.
4. By linear regression of these data, a standard curve was constructed which helped in
the extrapolation of concentration of cDNA present in the samples as copy numbers.
5. The raw fluorescence data from the reporter dye in every well was plotted by the
software. This was analysed to create a critical threshold and use this value to provide
any Ct values.
53
Statistical Methods
The median Ct values and the median viral load (as copy numbers) values were
calculated across the mild, moderate and severe categories. They were compared
against the clinical category obtained after applying the modified Vesikari scoring
system using the non parametric Kruskal Wallis test.
54
RESULTS
A total of 124 fecal specimens from children <5 years of age satisfying the inclusion
criteria were included in the study. Information regarding the number of days of
diarrhea, frequency of diarrhea in a 24 hour period, number of days of vomiting and
its frequency, dehydration, temperature and treatment received by the child were
captured on the case report forms of each child. In addition to this, information about
other concomitant infections, the diagnoses made and the treatment given was also
captured. Information on time taken for recovery from diarrhea was obtained from all
the children admitted to inpatient wards.
The study algorithm was followed and only samples which were positive by enzyme
immunoassay (Rotaclone) were included. RNA extraction, reverse transcription and
real-time PCR were performed on these 124 samples. Though 150 samples with 50
from each category respectively were aimed for, in the stipulated period only 124
samples could be obtained and analysed. The corresponding Vesikari score categories
were 22„mild‟, 62„moderate‟ and 40 „severe‟. After real time PCR was performed,
two samples from „mild‟ category had to be left out of analysis because there was no
amplification seen and hence the final number of samples analysed were 122.
55
Demographic data
Twenty nine samples were obtained from children who were brought to the paediatric
out-patient and emergency departments and 63 samples were from children admitted
to the inpatient wards. The above two sets of samples were collected as part of the
National Rotavirus Strain Surveillance Program from children < 5 years of age.
Another 32 samples were taken from a community based study in children with
rotavirus diarrhea. Children recruited into this study belonged to an urban slum
setting. They were brought by the mothers to the study clinic established in that area
by the Wellcome Trust Laboratory. The samples were all collected from symptomatic
children under 5 years of age.
16.30%
50.80%
32.70%
0
Percentage of children in each category
mild
moderate
severe
56
The mean age in children from the hospital based samples was 13.8 months (SD 9.23)
and from the community samples was 7.75 months (SD 1.86). The overall mean age
of the children was 12.08 months (SD 7.96). Children from the community are of
younger age group when compared to the children attending the main hospital.
Gender distribution
73.70%
26.20%
Sample distribution
Hospital based
community study
65%
34%
Gender distribution in
hospital based samples
male
female
71.80%
28%
Gender distribution in
community based samples
Male
Female
57
Two thirds of the children enrolled into the study are males and the remaining one
third are female children. This ratio is maintained in the hospital based samples
whereas it is more in the community based samples.
Age distribution
The age groups ranged from 2 months to 46 months. The majority of the children were
older than 6 months of age.
Other Clinical details
Of the 32 samples collected from the community, 15 children (44%) presented with
upper respiratory tract infection and one child had chicken pox. All the children were
managed conservatively at home with oral rehydration solution for diarrhea. None of
them received intravenous fluids.
The most common medications prescribed to children attending the hospital out-
26%
46%
23%
5.70% 2.40%
Percentages of children in different age groups
<6 months
7 - 12 months
13 - 24 months
25 - 36 months
>36 months
58
patient department was zinc sulphate suspension and oral rehydration salts. Among
the children admitted to the inpatient paediatric wards, 3 children presented with
sepsis of which one child was admitted to the intensive care unit. One child had
urinary tract infection, one had dengue and another child presented with
hypoglycaemia. Three fourths (74.6%) of the children admitted to the in- patient
wards received intravenous fluids followed by supervised oral rehydration therapy.
The other one fourth (24.7%) of hospitalised children received only supervised oral
rehydration treatment while monitoring for signs of worsening dehydration. All the
children recruited into the study recovered completely from diarrhea.
Data pertaining to the Vesikari scores
Data regarding the scores for each component of the Vesikari scoring was collected
from the case report forms and entered into excel sheet. The mean and median
Vesikari scores were calculated. Vesikari scores ranged from 3 to 15.
Table 6. Mean and median Vesikari scores in the different categories
Category Vesikari score Mean (SD) Median
Mild 4.71 (SD 0.64) 5
Moderate 7.91 (SD 1.34) 8
Severe 12.65 (SD 1.31) 13
The mean and median Vesikari scores in the samples collected from the community
and hospital were 8.43 (SD 2.97), 8 and 9.13 (SD 3.1), 9 respectively.
59
More than half of the children presented with vomiting along with diarrhea and a third
of the children presented with temperature above 37ºC.
Almost all the children (except four) received treatment either in the form of oral
rehydration salts or intravenous fluids, with 39.3% receiving intravenous fluids
followed by supervised oral rehydration. The mean and median duration at recovery in
hospitalised children are 2.1 (SD 1.01) and 3 days respectively.
Crossing points (Ct values) which were obtained in the real time PCR runs were used
to calculate the viral load. Ct is a direct correlate of viral load and hence these values
were plotted against the various parameters to study the possible associations.
The crossing points ranged between 13.8 and 38.9. There was no association between
the crossing points and the age even after adjusting for the site of recruitment of
children (hospital or community, p value 0.09). There was no significant difference in
crossing points between the community samples and hospital samples.
86%
61%
33%
51.50%
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
Diarrhea for ≤ 4 days Vomiting Temperature Dehydration
Percentage of children in different components of the scoring
system
60
Scoring of the individual components of the Vesikari scoring system
1. Duration of diarrhea
Majority of the children presented with diarrhea lasting for 1 to 4 days
Table7. Median and mean Ct values with confidence intervals across the
individual scores of ‘duration of diarrhea’.
Duration score Median Ct Mean Ct 95% confidence
Intervals
1 29 29.3 28.46 – 30.15
2 27.8 27.5 23.3 – 31.6
3 28 27.43 23.15 – 31.7
The median duration of diarrhea at the time of presentation to the hospital was 1 to 4
days and it remained the same across all the age groups. Applying the Kruskal Wallis
86%
8.20%
5.70%
Percentage of children across individual scores for
diarrhea duration
Diarrhea 1-4 days
5 days
≥ 6 days
61
test, there was no significant association found between number of episodes of
diarrhea and median Ct values (p value 0.62).
2. Number of episodes of diarrhea
Majority of the children (70%) had more than six episodes of diarrhea in a 24 hour
period.
Table 8. The median and mean Ct values along with confidence intervals across
the individual scores of ‘number of episodes of diarrhea'
Vesikari Score
Category
Median Ct Mean Ct 95% Confidence
Intervals
1 32 32.06 29.78 – 35.13
2 28 27.02 24.61 – 29.22
3 28 29.14 28.28 – 29.99
0.00% 10.80%
19.60%
69.60%
Percentage of children across the scores for episodes of
diarrhea in a 24 hour period
No diarrhea
1-3 episodes
4-5 episodes
≥ 6 episodes
62
Applying the Kruskal Wallis test, there was a significant association observed
between the number of episodes of diarrhea and the median Ct values (p value 0.031).
3. Duration of vomiting
More than 60 percent of children presented with vomiting along with diarrhea and
55% had vomiting lasting for 1 to 2 days before they were brought to the health care
facility.
Table 9. Median and mean Ct values with confidence intervals across the
individual scores for ‘duration of vomiting’
Vesikari score for
duration
Median Mean 95% Confidence
Interval
0 28 28.8 27.3 – 30.4
1 29 29.3 27.6 – 31
2 28.5 28.8 27.5 – 30.1
3 30 29.6 27.5 – 31.7
38.50%
27.80%
27%
6.50%
Percentage of children across the scores for vomiting duration
No vomiting
1 day duration
2 days
≥ 3 days
63
Applying the Kruskal Wallis test, there was no association observed between the
duration of vomiting and the median Ct values (p value 0.94).
4. Number of episodes of vomiting in a 24 hour period
Majority of the children presented with vomiting along with diarrhea.
Table10. Median and mean Ct values with confidence intervals across the
individual scores for ‘number of episodes of vomiting in a 24 hour period’
Vomiting episodes
score
Median Ct Mean Ct 95% Confidence
Interval
0 28 28.8 27.3 – 30.4
1 29 29.8 27.7 – 31.9
2 29 29.04 27.4 – 30.6
3 29 28.72 27.2 – 30.19
38.50%
18%
20.40%
22.90%
Percentage of children across the scores for 'number of
episodes of vomiting in 24 hour period
No vomiting
1 episode
2-4 episodes
≥ 5 episodes
64
Applying the Kruskal Wallis test, there was no association observed between the
number of episodes of vomiting in a 24 hour period and the median Ct values (p value
0.48).
5. Temperature
About 33 percent of the children presented with temperature above 37ºC.
Table 11. Median and mean Ct values with confidence intervals across the
individual scores for ‘temperature’
Temperature
score
Median Ct Mean Ct 95%
Confidence
Interval
0 28.5 29.1 28.1 – 30.1
1 28 28.6 27.1 – 30.2
2 26 28 23.2 - 32.7
3 24 24
67.20%
27.8
40.8
Percentage of children across the scores for 'temperature'
<37ºC
37.1-38.4ºC
38.5-38.9ºC
≥39ºC
65
Applying the Kruskal Wallis test, there was no association observed between the
temperature recorded and the median Ct values (p value 0.5)
6. Degree of dehydration
About half the number of children recruited presented with dehydration
Table 12. Median and mean Ct values with confidence intervals across the
individual scores for ‘degree of dehydration’
Dehydration score Median Ct Mean Ct Confidence Interval
0 28 29.2 28 – 30.3
2 28 28.7 27.5 – 29.9
3 27 27.2 24.8 – 29.5
48.30%
47.50%
4%
Percentage of children across the scores for dehydration
No dehydration
some
dehydration
severe
dehydration
66
Applying the Kruskal Wallis test, there was no significant association observed
between the degree of dehydration and median Ct values (p value 0.57).
7. Treatment
3% of the children were reassured and sent back without any treatment (score 0). A
majority of children (nearly 60%) received received oral rehydration therapy.
Table 13. Median and mean Ct values with confidence intervals across the
individual scores for ‘Treatment’ component
Treatment score Median Ct Mean Ct 95% Confidence
Interval
0 32.1 32.17 27.8 – 36.4
1 28 28.9 27.8 – 29.9
2 29 28.7 27.4 – 30.1
3%
57.30%
39.30%
Pecentage of children across the scores for treatment
No treatment
Rehydration
Hospitalization
67
Applying the Kruskal Wallis test, there was no association observed between the
treatment administered and the median Ct values (p value 0.73).
Real time PCR runs
The samples were divided into five batches and real time PCR was performed over
five different runs. The viral load was assessed in terms of crossing point (Ct) which is
the real time PCR cycle number where fluorescence crossed the threshold.
Statistical analysis
All the information was entered in Excel spread sheets. Statistical analysis was done
using SPSS version 17. Descriptive statistics like percentages, median, interquartile
range and frequencies were calculated. Kruskal Wallis test was used to study the
correlation between Ct values and severity on the Vesikari scoring system and also to
study the correlation between the crossing points and the different parameters of
Vesikari scoring system. Two of the 124 samples had undetermined crossing points
and were excluded from analysis.
Validity of the assay
The negative control and „no template‟ control included with each batch had Ct values
greater than 38.The positive control included with each batch had a Ct value within 2
cycles of the previous run and the Ct values ranged from 22 to 26. R2 value obtained
using the standards was > 0.9. Efficiency obtained using the standards in all the runs
varied between 96% -98%.
68
Table 14.Validity of the Real time PCR runs
Real time PCR
batch
Efficiency Slope R2
1 95.92 -3.4 0.99
2 96.45 -3.4 0.95
3 97.1 -3.3 0.99
4 97.1 -3.3 0.99
5 98.04 -3.4 0.95
Reproducibility of the assay
A control VP6 plasmid was included with each PCR run and the crossing points of
each dilution of the tenfold dilutions of the plasmid were similar across all the 5 runs.
The plasmid dilutions and cDNA of each sample were assessed in duplicates,
The crossing points (Ct) of the samples ranged between 13.8 and 38.9
69
Figure 13
Serial dilutions of standard VP6 plasmid dilutions across the five real time PCR
runs
Table15. Median Ct values in the different categories
Category Median Ct Inter quartile range
Mild 32 29.5– 36.5
Moderate 28 26 - 31.5
Severe 29 27 – 31
0
5
10
15
20
25
30
35
1 2 3 4 5
Cro
ssin
g p
oin
t
Assay run
Control 1 in 100 (SD 0.440) Control 1 in 1000 (SD 0.44)
Control 1 in 10000 (SD 0.42) Control 1 in 100000(SD 0.22)
Control 1 in 1000000(SD 0.3) Control 1 in 10000000(SD 0.48)
70
Though the median Ct values of the samples in mild category were higher than those
in the moderate and severe categories, there is little gradation observed between the
moderate and severe categories.
Figure 14. Box plot representing the median Ct in the different categories
The median Ct value is lowest in the „moderate‟ category which implies a high viral
load when compared to the mild and severe categories, but the linear regression shows
no correlation between severity of gastroenteritis and virus excretion (p=0.16) .
71
Figure 15. Scatter plot of Vesikari scores with Crossing points
72
DISCUSSION
Diarrhea is the second leading cause of childhood mortality and rotaviruses are
responsible for more than one third of these cases (2). The widespread use of
molecular biology based techniques, are contributing to better understanding of the
epidemiology of rotaviruses. Studies conducted so far on circulating genotypes
convey that more than a single genotype exist in a particular geographical region and
there are also periodic fluctuations in the circulating strains with the emergence of
unusual strains intermittently. Environmental contamination with faeces and living
conditions where the domestic areas are in close proximity to animals is not an
uncommon feature in developing countries. The possible explanation for the constant
emergence of new genotypes is the segmented nature of the genome and the
reassortment taking place between human and animal strains.
The virus replicates in the gut and hence measurement of viral load in stool samples is
a marker of its replication. Studies have shown a correlation between severity of
diarrhea and viral load in faecal samples and also antigenemia in serum. Real time
polymerase chain reaction helps in quantitation of viral load and its use in rotavirus
studies enabled the study of the shedding patterns and associations with various
pathophysiological aspects of rotavirus diarrhea. The current study was intended to
study the correlation between severity of diarrhea and viral load. The study employed
the Vesikari scoring system which is the best-known and the most frequently used
scoring system in assessing severity of diarrhea measuring valid end points with
minimal inter individual variation (115).
73
Faeces samples from children with gastroenteritis positive by Rotaclone EIA, had
RNA extracted and reverse transcription followed by real time PCR was performed.
The samples were broadly divided into hospital based samples which were collected
from children attending the out-patient and emergency department and admitted to
paediatric wards and community based samples collected from children attending the
community clinic in a urban slum area of Vellore. The mean age of all the children is
12 months (SD 7.96). In this study rotavirus affected majority of the children between
7 to 14 months (IQR 7 – 14). This age group corresponds to that period when the
passively acquired maternal antibody levels in the child starts to wane.
Vesikari scores ranged from 3 to 15. The difference in the mean Vesikari scores
between hospital based samples (8.4 and SD 2.97) and community based samples
(9.13 and SD 2.97) was not statistically significant. The majority of the samples had
Vesikari scores between 6 and 12 (IQR 6 – 12) implying most of the samples had
moderate diarrhea as opposed to mild and severe categories.
Crossing points in real time PCR, being a direct correlate of viral load, were analysed
with the components of the Vesikari scoring system. There was no correlation
observed between the severity of diarrhea and the rotavirus load. However, when the
individual components of the Vesikari score were analysed for any association with
the viral load, there was a significant negative correlation seen between the number of
episodes of diarrhea in a 24 hour period and crossing points on the real time PCR
indicating that the greater the number of diarrheal episodes the greater is the viral load
(p value 0.031). This is in agreement with findings from a previous study conducted
on rotavirus quantitation using real time PCR where there was a significant correlation
74
between the number of episodes of diarrhea and viral load (6). However, the same
study showed significant association between severity of diarrhea and viral load. The
current study did not reveal any significant associations between the other individual
components of the scoring system and the viral load. The incubation period in
rotavirus infection is 48 hours and viral excretion is expected to be high in the initial
days of diarrhea. There was no association between duration of diarrhea and viral load
probably because of unavoidable delays in bringing the children to health care facility.
The scoring on most of the hospital based samples including the in-patient samples
was mostly carried out in the busy Paediatric emergency department. Dehydration
which is more commonly seen in rotavirus diarrhea is prone to be scored subjectively.
The symptoms may worsen if adequate rehydration measures are not taken
immediately and this increase in severity may not be directly related to increase in
viral load. Modifications in the scoring system with reference to degree of dehydration
have been introduced in some studies to ensure wider acceptance (115).
LIMITATIONS OF THE STUDY
Limitations of the study include lack of testing for other aetiology of gastroenteritis
and lack of controls with asymptomatic infection. Though care was taken to ensure
that cold chain was maintained, the time interval which elapsed between collection of
stool specimen from the child till it was transported to the laboratory was not
recorded. Its bearing on viral load estimation cannot be completely ignored.
Genotyping of rotavirus was beyond the scope of the study. Certain genotypes are
associated with more severe diarrhea whereas others are asymptomatic in
75
presentation. On the other hand, the same genotype may exhibit different clinical
presentations in different geographic locations (57,116).
A previous study on the protective effect of natural rotavirus infection in an Indian
birth cohort showed that more than half the children were infected by the age of six
months (59). Almost 90% of the children acquire antibodies against rotavirus by the
age of 5 years, and prior infections confer some degree of protection from subsequent
infections (59,92). The level of already existing antibodies may also contribute to
mismatch between severity and viral load.
A small representative amount of 0.2gm of the stool sample was processed. Measuring
the total amount of stool passed by the child each day would lead to more accurate
quantitation, since both frequency and volume of stool in gastroenteritis may reflect
gut damage and virus replication.
The Vesikari scoring system is widely used, but conclusions on viral load can be
drawn only if strict adherence to measuring the individual parameters of the scoring
system is followed while taking into consideration other factors including existing
antibody levels and genotypes.
76
CONCLUSION
In this study to quantify rotavirus load using real time PCR and correlate viral load
with clinical severity using the Vesikari scoring system, there was no significant
correlation studied between the severity of rotavirus gastroenteritis and the viral load.
However, with increasing episodes of diarrhea, the viral load also increased.
77
APPENDIX
ENZYME IMMUNOASSAY USING PREMIER ROTACLONE® KIT
Materials Required
Equipment: Microplate reader, Pipettes, Pipette tips, Refrigerator, Biological Safety
Cabinet
Reagents
Premier Rotaclone®
Deionized water, pyrogen free
Bovine Rotavirus lysate – Internal Control
Procedure
All the reagents were thawed and brought to room temperature before testing and
replaced at 2 – 8°C soon after use. It was ensured that the wells did not dry between
the steps. All the kit components were labelled with the date they were opened before
proceeding with the ELISA.
Sample Preparation
Using the diluent provided in the kit, a 10% fecal suspension was prepared. This could
be used for upto 3 days when stored at 2 – 8°C without affecting the assay outcome.
This fecal suspension was vortexed for 15 minutes at room temperature to emulsify in
the diluent. Then it was left to stand at room temperature for the sediment to settle at
the bottom.
78
Steps
1. The required number of wells were set in the microtitre well holder.
2. Two drops of diluted fecal sample, positive control, negative control (sample diluent)
and 100 µl of bovine rotavirus (BRV) were added to the bottom of separate wells.
3. Two drops of enzyme conjugate were added to each well. All the reagents in the wells
were mixed by gently swirling it on the table top.
4. After step 3, the plate was allowed to incubate at room temperature for 1 hour.
5. The liquid in the wells was poured out and the microtitre well plate is held upside
down and tapped vigorously against absorbent paper to ensure complete removal of
the reagents from the wells.
6. All the wells were filled to the brim with milliQ water, which was then poured out and
the wells tapped vigorously against absorbent paper.
7. This washing procedure was repeated four times.
8. Two drops from substrate A solution were added to each well.
9. Two drops from substrate B solution were added to these wells.
10. The microtitre well plate with all the reagents in it was incubated at room temperature
for 10 minutes.
11. Two drops of stop solution were added to each well.
12. The absorbance of each well was read at 450 nm for the Optical Density (OD) values.
79
Data interpretation
Validity criteria
1. The validity of the assay was evaluated by the BRV values which was used as the
internal control. The range had to be 0.8 -0.9.
2. The cut off value for positive control had to be greater than 0.150.
3. The cut off value for negative control had to be less than 0.150.
Acceptance Criteria
1. The samples were considered positive for rotavirus if the absorbance units (A450) was
greater than 0.150.
2. If the absorbance was less than or equal to 0.150 , the samples were considered
negative for rotavirus.
3. The samples had to be retested if the validity and acceptance criteria were not
obtained.
80
RNA EXTRACTION USING QIAGEN KIT METHOD
Materials
Equipment: Pipettes, Pipette tips, Disposable gloves, Microcentrifuge tubes, Vortex
shaker, Biological Safety Cabinet, Ultracold freezer, Centrifuge
Reagents
QIA amp Viral RNA Mini Spin Kit Qiagen
Controls:
Positive Control which is a known rotavirus positive fecal suspension
Negative Control which is a known rotavirus negative fecal suspension
Water control : DEPC treated water
Procedure
Preparation of 20% Fecal Suspension
This is made by using Minimal Essential Medium. Fecal specimens which are ELISA
positive were stored at -70°C. These were taken out, thawed and brought to room
temperature. About 0.2gm or 200µl of stool was measured and taken in a
microcentrifuge tube.
One ml of minimal essential medium was added and vortexed for 1 minute.
Centrifugation was carried out at 10000 rpm for 5 minutes. Faecal extracts were stored
at -20°C to -70°C until RNA extraction
81
RNA EXTRACTION
RNA extraction is carried out using Qiagen kit extraction method (QIAamp®
Viral
RNA minikit). RNA extraction is carried out in three steps using the spin columns
provided with the kit. These spin columns fit well into any standard microcentrifuge
tube. These tubes are RNase free.
Adsorption to the QIAamp membrane
Viral RNA is adsorbed onto silica-gel membrane during centrifugation. Salt and pH
conditions in the lysate makes sure that proteins which inhibit the
downstreamreactions are not retained on the QIAamp membrane.
Removal of residual contaminants
Two wash buffers AW1 and AW2 wash the RNA bound to the membrane and make it
free of contaminants.
Elution
Buffer AVE which is RNase free water that contains 0.04% sodium azide prevents
microbial growth and resulting RNA contamination.
Preparation of reagents
Addition of buffer AVE to Carrier RNA
AVE buffer was checked for any precipitates and was made precipitate free.
AVE buffer (310µl)was added to the vial containing lyophilised carrier RNA. The
needed volume of this was used (up to a maximum of 6 times) and the rest stored at 2
82
to 8°C. When needed, an appropriate volume of this AVE-carrier RNA is mixed with
stipulated amount of AVL as per the protocol standards and used.
Buffer AW1
This buffer is available as a 25 ml concentrate and before using it, 19ml of absolute
alcohol (100% ethanol) was added to it to make up to a final volume of 44ml.
Buffer AW2
This buffer is also available as a 13 ml concentrate and before using it, 30 ml of
absolute alcohol is added to it to make upto a final volume of 43 ml.
Handling of spin columns
The following precautions were taken to overcome cross contamination in view of the
sensitivity of the nucleic acid amplification techniques.
The sample was carefully pipetted and applied to the spin column without wetting the
rim of the spin column.
Aerosol- barrier tips were used and pipette tips were changed between the transfer
steps.
After each pulse vortexing step, the spin columns were spun briefly to remove drops
accumulated towards the inside portion of the lid.
Gloves were worn throughout the procedure and were changed everytime they got into
contact with the sample accidentally.
83
Spin Protocol
The spin columns were always set in the respective collection tubes and remained
closed. Only when adding reagents, they were opened one at a time.
After adding the necessary reagents, the spin column was closed and centrifuged. The
filtrate obtained in the collection tube was discarded and the column was transferred
to a new collection tube. Before starting the extraction procedures the samples and
reagents were thawed and brought to room temperature before starting the extraction
procedure.
Steps
1. 560 µl of the already prepared AVL containing carrier RNA was pipetted into a
microcentrifuge tube.
2. 140 µl of the fecal extract supernatant was added to it. They were mixed by pulse
vortexing for 15 sec .
3. After step 2, incubation was carried out at room temperature (15-25C) for 10 minutes.
Viral particles lyse completely in this duration. AVL also inactivates RNases and
other infectious agents.
4. Brief centrifugation was carried out to remove any droplets that accumulated on the
underside of the lid while carrying out the previous steps.
5. 560 µl of ethanol was taken into these centrifuge tubes and mixed by pulse-vortexing
for 15 seconds. A brief centrifugation was carried out to remove droplets under the lid.
Only ethanol was used in this step as other alcohols are likely to reduce the RNA
yield.
84
6. 630 µl of sample from step 5 was pipetted carefully into a QIAamp spin column
nested in a 2ml collection tube. Adequate measures were taken not to wet the rim of
the spin column. This was centrifuged at 8000 rpm for 15 seconds and the spin
column was carefully transferred into a second clean collection tube. The filtrate from
the first collection tube was discarded.
7. With another 630µl from the microcentrifuge tube taken into the spin column, step 6
was repeated.
8. 500µl of AW1 buffer was pipetted into the spin column after carefully opening the
cap and then closed. This was centrifuged at 8000 rpm for 1 minute and the spin
column was transferred to another clean collection tube. The filtrate collected was
discarded appropriately.
9. The spin column cap was carefully opened and 500µl of AW2 buffer was added to it.
Centrifugation at full speed, i.e. 13200 rpm, was carried out for 3 minutes.
10. The spin column was placed in a microcentrifuge tube which was not provided with
the kit. The old collection tube with the filtrate was discarded.
11. 60µl of AVE buffer which was at room temperature was pipetted into the spin column
after carefully opening it. The spin column was closed and left to stand at room
temperature for 1 minute.
12. The microcentrifuge tube along with the column was centrifuged at 8000rpm for 1
minute. This is enough to elute atleast 90% of RNA present in the spin column.
13. 40 µl of this eluted RNA was used for reverse transcription and conversion to cDNA
whereas the rest was stored at -70°C.
85
REAL TIME PCR
Procedure
1. Preparation of plasmid standards for quantitative PCR
2. The plasmid has 1010
copies per sample.Ten fold dilutions were made to obtain 109 to
101plasmid standards per 2µl sample for carrying out the real-time PCR.
3. Eight of these serial dilutions containing rotavirus VP6 fragment were included with
each run as positive control and to derive the standard curve for quantitation of the
virus from the fecal specimen.
4. One set of the diluted plasmids was stored as stock plasmid at -70°C
Preparing the Real time PCR Master Mix
1. Master mix was aliquoted before use.
2. Working concentrations were prepared and labelled accordingly.
3. Preparation of the Mastermix was carried out in the clean room.
4. All the reagents were thawed first and then briefly vortexed and centrifuged.
5. Reagents required for 1 sample of cDNA
Taqman Mix 12.5µl
VP6- F Primer 2.0 µl
VP6- R Primer 2.0 µl
VP6- Probe 0.125 µl
H20 8.3 µl
86
6. 23 µl of the above reagents mix was added to 2 µl of the cDNA obtained from the
fecal specimen.
Addition of samples and controls
1. 2µl of the sample cDNA was added to 23µl of master mix.
2. Gloves were changed frequently and adequate care taken to avoid cross
contamination.
3. Once cDNA was added to the master mix, the wells were firmly fitted with caps.
4. Samples for standard curve were included in every run for absolute quantitation.
5. The strips after sealing with the caps underwent spinning to remove any bubbles.
Running the Reactions
1. ABI 7500 Fast Real Time PCR machine was used. The computer and the machine
were switched on first.
2. The strips with the cDNA and master mix were loaded into the real time machine.
3. The ABI 7500 software was accessed to prepare the template.
4. On the real time software, the wells were labelled accordingly. The standards were
labelled „standard‟ and the samples along with a known positive and negative were
labelled „unknown‟. A no template control was included and labelled „negative‟.
5. The number of copies in the known dilutions were entered against the sample identity
in the template provided.
87
6. The run method belonging to “Invitrogen Rota quantitation using VP6 probes and
TaqMAN chemistry” was selected from the panel displayed so that the preset
temperatures would take over automatically.
7. After loading the strips and setting the run method, the „start run‟ button was selected
and the program commenced.
8. After completion of a run, the analysis tools were used to analyse the data. The
standard curves were checked for a good slope and R2 value (A perfect slope would be
-3.3 and R2 1).
9. The data was analysed in Microsoft Excel 2010.
88
BIBLIOGRAPHY
1. Tate JE, Chitambar S, Esposito DH, Sarkar R, Gladstone B, Ramani S, et al.
Disease and economic burden of rotavirus diarrhoea in India. Vaccine. 2009 Nov
20;27 Suppl 5:F18–24.
2. Tate JE, Burton AH, Boschi-Pinto C, Steele AD, Duque J, Parashar UD. 2008
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Ofiice ofthe Addl. Vice Principal (Research)
Ret Res/09/2011 ,
Dr. P Susmitha Karuna$e€PG RegistrarDepartment of MicrobiologyChdstian Medical CollegeVe ore 632 002
Cbrisiaa Medical College,Vellore 632 002
February 16,2012
Sub: FLUID Research grrnt project NEW PROPOSAL:Quantitation of Grcup A Rotavirus by real-time polymerase chain reactiol inchildren with varying sevedty of gashoent€ritisDr. P Susmitha Karunasree PG Registrar, Microbiology, Dr. Gangandeep KangGl Sciences, Dr, Anna Simon, Dr. Leni Malhew, Dr. Indim -A.garwal, Dr.Prabhakar D. Moses, Dr. Kala Ebenezer, Child Health Unit IV, Dr. Sudhir Babji,Wellcome Trust Research Labontory.
Ref: IRB Min. No. 7744 dated,6.2-2012
I enclose the following documents:-
*-t'---.isft uri6E"l-Rede.r.r€.'4apploEl2. Agreement
Coutd you pteaie sign the agreement and send it to I)r. Nihal Thomas, Addl. VicePrincipal @esearch), so that the grant money can be released.
ics Comminee)
trffih\s4
INSTITUTIONAL REVIEW BOARD (IRB)
CHRISTIAN MEDICALVELLORE 632002,
COLLEGEINDIA
Dr,B.J.Prrshrnth.m, M.A.,M-A.,Dr.Min(Clhicrl)Diector Chdstian Counseling C€nt'eEditor, Indian Joumal of Psychological CouselingChairpeNon, Ethics Conmittee, IRB
Dr. Alfred Job Dadel Ms orthoChairperson, Research Committee &Principal
Dr. Nihll ThomasMD, MNAMS, DNB(Edo), FRACP(f,trdo), rRcP(Ddi!)Secretary, Ethics Committee, IRBAdditional \4ce Principal (Research)
February 16, 2012
Dr. P Susmitha KarunasreePG RegistrarDepartrnent of MicrobiologyChristian Medical CollegeVellore 632 002
Sub: FLUID Research grant project NEW PROpOSAL:Quantitation ofGroup A Rotavirus by real-time polymerase chain reactron mchil&en with varying severity of gastoenteritisDr. P Susmitha Karunasree, PG Registrar, Microbiology, Dr. Gangandeep Kang, GISciences. Dr, Anna Simon, Dr. Len l"lat\cu:, Dr. Indira AganYal. Di. prabhakar D.Moses, Dr. Kala Ebenezer, Child Health Unit IV, Dr. Sudhir Babji, Wellcome TrustResearch Laboratory.
Ref: IRB Min. No. 7744 darcd 6.2.2012
Dear Dr. Kartuusree,
The Institutional Review Board (Blue, Research and Ethics Committee) ofthe ChrisrianMedical College, Vellore, reviewed and discussed your project entitled ,,euantitation ofGroup A Rotavirus by real-time polyrnerase chain reaction in children with varying severity ofgastroente tis" on Februaty 6,2012.
The Committees reviewed the following documents:L Format for application to IRB submission2. Patient Information Sheet and Consent Form (English and Tamil)3. Case reporling lorm4. Cv of Drs. Gagandeep Kang, Indira Agarwal, Sudhir Babji, prabhakar D
Moses. Lenin Grace Mathew5. A CD coniaining documents | 4 ;
FAX I O4LE - 2262744, 22U4ALrEL . O4L5 - 2244294. 2244202 E-mail : research@cmcvellore.ac.in
..i,
ffiB\*g
INSTITUTIONAL REVIEW BOARD CIR3)CHRISTIAN MEDICAL
VELLORE 632002,COLLEGEINDIA
Dr.B.J.PnshanthaE, M.A.,l[.A,]Dr.Min(ClinicaDDireclot Christian Counseling CentreEditot Indian Jourtral of Psychological CounselingChairpenon, Ethics Committee, IRB
Dr. Alfted Job Dsniel, MS OrthoChairpersoD, Research Commiat€e &Principal
Dr. Nihd ThomasMD, MNAMS, DNB(xrdo); FRACP@Ddo), rRcP(Edi!)Secretary, Ethics CoEmittee, IRllAdditional \,ice Principal (Research)
The following Institutional Reviev/ Board (Ethics Comiittee) members were present at themeeting held on February 6, 2012 in the CREST/SACN Conference Room- Christian MedicalCollege, Bagayam, Vellore- 632002.
We approve the project to be conducted as presented.
The Institutional Ethics Cornmittee exp€cts to be informed about the progress ofthe project, anyse ous adverse events occuring in the course of the project, any changes in the protocol and thepatient information-/infomed consent and requires a copy of the final riport.
Name Qualification Designation Other AffiliationsDr. B.J.Prashartham MA (Counseling), MA
(Theology), DrMin(Ctinical)
Chairperson(lRB)&Director, ChristianCounselling Centre
Non-CMC
Mr. Harikishnan BL Lauryer Non-CMCMrs. S. Paftabiraman BSc, DSSA Social Worker, Vellore Non-CMC
Mm. Ellen EbenezerBenjamin(on behalfofDr.Jayarani Premkumar)
M.Sc. (Nursing), Ph-D. NursingSuperintendent, CMC.
Mrs. Shirley David(on behalfofDr.Jayamri Premkumar)
M.Sc. (Nurshg), Ph.D. NursingSuperintendent, CMC.
Dr. Nihal Thonas MD MNAMSDNB(Endo)FRACP(Endo)FRCP(Edin)
Secretary IRB (EC)& Dy.Chairperson (IRB),Professot of Endocrinolog.& Addl. Vice Principat(Research), CMC.
FM I O4rG - 22627aa, 22a44glrEL I 0476 - 22A4294,22a42O2 E-mail : research@cmcvellore.ac.in
TNSTITUTIONAI REVTEW BOARD (IRB)CHRISTIAN MEDICAL COLLEGE
VELLORE 632 OO2, INDIA
Dr.B.J.Prashanthrm, M.A,,M.A.pr,IIin(Crinicd)Director, Cbristian Counsetlg C€[tre,Edibr, lndian Joumal of Psycbological CouDseliDgChairpeNo4 Ethics Corffnittee, IRB
Dr. A|frcd Job Daniel, MS OrthoCadlp€rso4 Research Connittee &Principal
Dr. Nihal Thod.tMD, MNAMS, DNB(Endo), FRAcP(EDdo), IRcP(Edir)Secret ry, Ethics Committee, IRBAdditional Vice Principal (R€search)
A sum of{ 40,000/- (Rupees Forty thousand only) can be sanctioned for 12 months. Asubsequent installment of40,000/- will be released at the end of the fiIst year following thereceipt ofthe progess report (Total amount 80,000/-).
Institutional Review Boad
S.c.erctulnstitut;ondl Hc,r,ie!,,, ;oc.C
i t j th ics Corn.x j r r , r lChnslioD l.:..i_._ct a..l j.,.,,
Ve\ir.. 522 '112. tinn,l tiJ.j, jj.lic
,c
lEl : 0416 - 22a4294, 22A42O2 E-mail : research@cmo/ellore.ac.inFM I 0476 - 2262788, 228448L
Information to the Participant
Rotavirus is responsible for a majority of diarrhea related deaths in children below 5 years. 1 in
every 250 children die of diarrhea with this virus every year. Hence control measures are of
great need. Our country is trying to make vaccinations to suit our population and at the same
time are cost effective. Children presenting with diarrhea may have mild to very severe clinical
symptoms. This study is being done to see the amount of virus passed out in the stools of
children with diarrhea presenting with varying severity of symptoms. This can help us in the
long run to evaluate the upcoming vaccines in their ability to control this rotaviral diarrhea.
You are being requested to participate in the above mentioned study as it will help us develop a
good tool to measure severity.
What will you have to do?
If you wish to take part in the study, you will have to sign the consent form first and then collect
stool sample of your child in the container provided.
Will you have to pay for the tests to be done in the study?
You will not need to pay any amount towards the tests.
Can you withdraw from the study?
You can withdraw from participating in the study at any point of the study.
Will you personal details be kept confidential?
Information is taken in terms of severity of diarrhea and no personal details are sought.
For further queries please contact Dr. Susmitha (Mob No. 09944642476)
CONSENT TO PARTICIPATE IN THE STUDY
Study title:
Quantitation of Group A Rotavirus in children with varying severity of gastroenteritis.
Study Number:
Date of Birth / Age (in years):
I_____________________________________________________________
___________, parent/guardian of ___________________________________
(Please tick boxes)
Declare that I have read the information sheet provided to me regarding this study and have clarified
any doubts that I had. [ ]
I also understand that participation in this study is entirely voluntary and that I am free to withdraw
permission to continue to participate at any time without affecting any treatment or legal rights [ ]
I also understand that the tests done on the specimen will be done free of cost. [ ]
I understand that the child’s identity will not be revealed in any information released to third parties [ ]
I voluntarily give my consent to let my child take part in this study [ ]
Name:
Signature:
Date:
Name of witness:
Date:
Case Reporting Form
Date Hospital number:
Patient serial number
Address :
Diagnosis by the attending physician:
Age of the child: Date of birth: Sex of the child: M/F
Clinical information
Temperature: ____C
Vomiting : Yes/No Duration : ____ days Max no. of episodes in 24hrs: __
Diarrhea: Yes/No Duration: _____ days Max no. of episodes in 24 hrs: ___
Signs of dehydration:
Lethargy: Yes/ No Restless/ Irritable: Yes/No
Feeding well: Yes/No Eyes sunken: Yes/ No
Skin pinch: Normal ( ) slow return ( ) Very slow return ( )
Degree of dehydration: None ( ) some( ) Severe ( )
Treatment
Supervised oral / Intravenous rehydration
Laboratory Information
Rotavirus identified in stool by ELISA : Yes/ No
Person Completing the form: Signature
Vesikari Score:
S.No Hosp No Age Sex
Vesikari
score Category EIA OD Viral load Ct Sample ID
Diarrhe
a days
No.of
episodes
of
diarrhea
vomiting
days
no.of
episodes of
vomiting TemperatureDehydration Treatment AREAS
1 379430F 5 M 5 mild 2.601 20601.09 33.7 RQ 001 1 1 1 1 0 0 1 Hosp In
2 364484F 12 M 5 mild 0.579 3491.81 36.3 RQ 013 1 1 1 1 0 0 1 Hosp In
3 389329F 6 M 5 mild 1.214 67269.56 32 RQ 014 1 1 1 1 0 0 1 Hosp In
4 LBS 083 9 M 5 mild 1.306 399 36.9 LBF 435 1 1 1 1 1 0 0 Comm
5 LBS 075 9 F 3 mild 0.204 100.22 39.9 LBF 947 1 1 0 0 0 0 1 Comm
6 LBS 156 6 M 5 mild 0.518 106727.5 28.7 LBF 2077 1 2 0 0 1 0 1 Comm
7 LBS 241 7 M 5 mild 1.115 16632.39 31.3 LBF 4289 1 1 0 0 0 2 1 Comm
8 LBS 283 7 M 5 mild 0.473 344324.723 26.2 LBF 5232 1 3 0 0 0 0 1 Comm
9 LBS 003 11 M 5 mild 0.818 57108.806 32.2 LBF 6819 1 3 0 0 0 0 1 Comm
10 046246F 20 F 5 mild 0.194 3100.07 34.8 CM0221 1 3 0 0 0 0 1 Hosp In
11 294145F 3 M 5 mild 0.535 30840.5 29.8 CM0007 1 1 1 1 0 0 1 Hosp In
12 136433F 7 M 5 mild 0.328 137.22 38.4 CM0023 2 2 0 0 0 0 1 Hosp out
13 804918D 16 M 3 mild 3.262 807756 27.7 CM0023 1 1 0 0 0 0 1 Hosp in
14 852962D 14 M 5 mild 0.634 275498.5 27.9 CM0027 1 3 0 0 0 0 1 Hosp out
15 858213D 18 F 5 mild 1.723 20033.6 32.6 CM0205 1 3 0 0 0 0 1 Hosp out
16 098971F 8 M 5 mild 0.338 29494.05 31.6 CM0239 1 3 0 0 0 0 1 Hosp out
17 597502D 34 M 5 mild 0.909 976058.8 26.6 CM0289 1 3 0 0 0 0 1 Hosp out
18 046964F 3 M 4 mild 0.247 363.886 36.3 CM0423 1 3 0 0 0 0 1 Hosp out
19 032947F 10 F 4 mild 0.331 52283.2 31.2 CM0218 1 2 0 0 1 0 1 Hosp out
20 331778F 6 M 5 mild 2.071 423.947 36.8 CM0045 1 3 0 0 0 0 1 Hosp out
21 788941D 18 M 5 mild 0.164 157.694 39.7 CM0276 1 1 1 1 0 0 1 Hosp out
22 379621F 18 M 6 moderate 1.808 142779.9 27.5 RQ 007 1 1 1 1 0 0 1 Hosp out
23 384232F 16 M 6 moderate 1.323 71886 28.5 RQ 010 1 2 1 1 0 0 1 Hosp out
24 389328F 6 M 6 moderate 2.378 5572291.1 22.2 RQ 015 1 2 1 1 0 0 1 Hosp out
25 379497F 17 M 8 moderate 2.063 101727.5 28 RQ 009 1 1 1 1 1 2 1 Hosp out
26 LBS 211 6 M 6 moderate 1.469 193787.829 27.1 LBF 4473 1 3 0 0 1 0 1 Comm
27 LBS 008 11 M 6 moderate 2.095 168002.4 28 LBF 2497 1 3 0 0 1 0 1 Comm
28 LBS 308 7 M 6 moderate 0.261 2174.916 34.3 LBF 3744 1 1 0 0 0 2 1 Comm
29 LBS 054 8 F 6 moderate 2.757 134118.493 27.6 LBF 6648 1 2 1 2 0 0 0 Comm
30 LBS 187 6 F 8 moderate 3.033 28925.61 30.5 LBF 2332 1 3 1 1 1 0 1 Comm
31 LBS 059 11 F 10 moderate 3.056 406047.2 26.7 LBF 4008 1 3 2 3 0 0 1 Comm
32 LBS 217 7 M 7 moderate 0.281 279086.5 27.2 LBF 4158 1 3 0 0 0 2 1 Comm
33 LBS 257 6 M 8 moderate 1.079 87443.399 28.2 LBF 5791 2 3 0 0 0 2 1 Comm
34 LBS 329 6 F 10 moderate 0.605 389027.276 26.1 LBF 5816 1 3 1 2 0 2 1 Comm
35 LBS 024 9 M 7 moderate 1.185 1794970647 13.8 LBF 5937 2 2 0 0 0 2 1 Comm
36 LBS 094 9 F 9 moderate 0.566 20876.84 33.7 LBF 6279 1 2 1 1 1 2 1 Comm
37 LBS 301 6 M 7 moderate 0.541 56491.767 28.9 LBF 6405 1 3 0 0 0 2 1 Comm
38 LBS 269 6 M 10 moderate 2.272 137494.582 27.6 LBF 6573 1 3 1 1 1 2 1 Comm
39 LBS 084 7 M 7 moderate 2.767 104684.606 28 LBF 6810 1 3 0 0 0 2 1 Comm
40 LBS 227 7 M 8 moderate 0.528 3351629.754 22.9 LBF 7652 1 3 1 2 0 0 1 Comm
41 LBS 299 11 F 7 moderate 1.892 88727.1986 28.2 LBF 7680 1 3 0 0 0 2 1 Comm
42 LBS 216 9 M 9 moderate 0.342 55854.737 28.9 LBF 8409 1 2 1 2 0 2 1 Comm
43 389328F 6 M 7 moderate 1.514 147243.8 24.2 CM0149 2 3 0 0 1 0 1 Hosp out
44 367536F 12 M 6 moderate 1.119 30899070.8 19.7 CM0111 1 3 0 0 0 0 2 Hosp in
45 309472F 29 M 10 moderate 1.708 364302.726 26.2 CM0009 1 3 2 2 0 0 2 Hosp in
46 085396F 13 M 9 moderate 2.348 562765.25 25.5 CM0030 1 3 0 0 1 2 2 Hosp in
47 082213F 11 M 8 moderate 1.908 73435.84 31.9 CM0070 1 3 0 0 0 2 2 Hosp in
48 927039D 22 F 10 moderate 1.416 17641404.65 20.5 CM0074 1 3 1 1 0 2 2 Hosp in
49 347835F 12 F 8 moderate 1.822 59895.12 32.2 CM0076 1 3 0 0 0 2 2 Hosp in
50 170495F 8 M 8 moderate 0.498 9607.98 34.8 CM0100 1 3 2 2 0 0 0 Hosp in
51 367550F 12 M 7 moderate 2.118 298765.754 26.5 CM0114 1 2 0 0 0 2 2 Hosp in
52 374544F 28 M 8 moderate 0.78 116747.3883 24.5 CM0123 1 3 0 0 0 2 2 Hosp in
53 207201F 7 F 10 moderate 0.78 874050062.3 14.8 CM0124 3 2 0 0 1 2 2 Hosp in
54 180938F 6 M 12 moderate 0.626 1289.531 34.6 CM0130 1 3 2 2 0 2 2 Hosp out
55 189063F 8 F 8 moderate 0.701 60032.28 32.3 CM0133 1 3 0 0 0 2 2 Hosp In
56 379497F 13 M 10 moderate 0.887 18216.806 30.6 CM0134 1 3 2 2 0 0 2 Hosp In
57 001863F 18 M 10 moderate 0.244 340.18 36.5 CM0136 1 3 0 0 2 2 2 Hosp In
58 395521F 16 F 9 moderate 0.286 226662.925 26.8 CM0147 1 3 0 0 0 3 2 Hosp In
59 389329F 6 M 9 moderate 1.614 6387.42 32.1 CM0150 1 3 0 0 0 2 2 Hosp In
60 014698F 5 M 8 moderate 1.368 10074.27 31.6 CM0153 1 3 0 0 0 2 2 Hosp In
61 314159F 29 M 7 moderate 1.22 1253697.25 24.4 CM0168 1 3 0 0 1 0 2 Hosp In
62 411128F 7 M 10 moderate 1.682 179534.7 29.6 CM0180 1 2 3 2 0 0 2 Hosp In
63 054881F 15 F 9 moderate 0.465 186557.5 29.6 CM0186 1 2 2 3 0 0 1 Hosp In
64 113103F 14 F 9 moderate 1.83 3854479 23.6 CM0194 1 3 2 2 0 0 1 Hosp In
65 179904F 13 M 10 moderate 0.498 70556307.2 20.5 CM0197 1 3 2 3 0 0 1 Hosp In
66 406355F 6 F 8 moderate 0.939 28891.86 30.6 CM0204 2 3 0 0 2 0 1 Hosp In
67 259672F 8 F 8 moderate 2.585 394879.57 27.5 CM0218 1 3 0 0 0 2 2 Hosp In
68 352539F 3 F 8 moderate 3.078 174237.8 25.3 CM0231 1 3 0 0 0 2 2 Hosp In
69 244516F 9 M 7 moderate 2.647 4108985.4 23.9 CM0232 1 2 0 0 3 0 1 Hosp out
70 354842F 7 F 7 moderate 0.314 67283.73 32 CM0083 1 2 1 1 1 0 1 Hosp In
71 074615F 12 M 6 moderate 1.319 928560.6 26.9 CM0149 1 3 0 0 1 0 1 Hosp In
72 765652D 27 M 6 moderate 0.175 1058.966 34.7 CM0347 2 3 0 0 0 0 1 Hosp out
73 399797F 8 F 6 moderate 0.331 290323.52 25.00 CM0381 2 3 0 0 0 0 1 Hosp out
74 152136F 11 F 8 moderate 0.761 868091.4 27.6 CM0030 1 2 2 2 0 0 1 Hosp out
75 162180F 7 M 8 moderate 0.28 15179.92 29.60 CM0038 1 3 1 2 0 0 1 Hosp out
76 171179F 8 F 9 moderate 0.73 15093 32 CM0039 3 3 1 1 0 0 1 Hosp out
77 937094D 12 F 7 moderate 0.499 592652.4 27.6 CM0130 1 2 2 1 0 0 1 Hosp out
78 992345D 11 F 9 moderate 0.2 6807.9 34.2 CM0170 1 3 2 2 0 0 1 Hosp out
79 162155F 6 M 8 moderate 2.262 113246.50 26.6 CM0232 1 2 2 2 1 0 1 Hosp out
80 810872D 24 F 9 moderate 3.327 589665.9 26.5 CM0308 1 3 1 2 1 0 1 Hosp out
81 280282F 2 M 7 moderate 0.391 51045 31.5 CM0330 3 3 0 0 0 0 1 Hosp out
82 110480F 10 F 7 moderate 1.419 5607011.272 25.7 CM0334 1 3 1 1 0 0 1 Hosp out
83 200807F 15 M 11 severe 1.454 117567652.2 17.7 RQ 008 1 2 1 3 1 2 1 Hosp out
84 014698F 12 F 11 severe 1.031 91029421 21.5 RQ 016 1 2 1 1 0 0 1 Hosp out
85 LBS 060 12 M 13 severe 0.798 1836414.1 25.6 LBF 054 1 2 3 3 1 2 1 Comm
86 LBS 249 6 M 11 severe 0.318 66739.58 29.4 LBF 1831 3 3 1 3 1 0 0 Comm
87 LBS 321 6 M 12 severe 0.877 201699.5 28.6 LBF 4445 1 3 2 2 1 2 1 Comm
88 LBS 235 6 M 12 severe 1.166 2971795 23.2 LBF 4718 2 3 0 0 2 3 2 Comm
89 LBS 086 9 F 12 severe 1.01 57976.195 28.8 LBF 4995 1 3 2 3 0 2 1 Comm
90 LBS 195 7 M 13 severe 0.849 71936.052 28.5 LBF 5633 3 3 2 2 0 2 1 Comm
91 LBS 157 8 F 12 severe 1.386 105079.659 27.8 LBF 5979 3 3 1 1 1 2 1 Comm
92 LBS 183 6 M 14 severe 0.323 22024.809 30.2 LBF 7307 1 3 3 3 0 3 1 Comm
93 LBS 272 7 M 12 severe 0.173 316051.3844 26.4 LBF 8800 1 3 2 3 0 2 1 Comm
94 002992F 13 M 13 severe 2.432 25422.05 30 CM0002 1 3 1 3 1 2 2 Hosp in
95 835864D 21 M 15 severe 0.159 18723.6088 30.5 CM0004 2 3 3 3 0 2 2 Hosp in
96 304506F 3 M 12 severe 3.212 50715.54 29 CM0006 1 3 2 2 0 2 2 Hosp in
97 309760F 14 F 13 severe 0.883 192014.258 27.1 CM0015 1 3 2 3 0 2 2 Hosp in
98 341986F 18 F 13 severe 1.112 235272.0098 26.8 CM0059 1 3 2 1 1 3 2 Hosp in
99 347401F 19 M 12 severe 1.13 2467.023 33.4 CM0067 1 3 1 2 1 2 2 Hosp in
100 080788F 16 M 11 severe 1.767 7044.4 35.3 CM0073 1 3 1 1 1 2 2 Hosp in
101 299574F 10 M 13 severe 0.733 1453710.47 24.1 CM0081 1 1 2 3 2 2 2 Hosp in
102 119944F 10 M 13 severe 2.34 54757.63 28.9 CM0082 1 3 2 3 0 2 2 Hosp in
103 540414D 39 M 14 severe 0.697 672.8373 36.9 CM0087 1 3 2 3 1 2 2 Hosp in
104 361083F 44 F 11 severe 1.743 14029.364 30.9 CM0088 1 2 2 2 0 2 2 Hosp in
105 119098F 13 M 12 severe 1.55 1335170.527 24.3 CM0098 1 3 2 2 0 2 2 Hosp in
106 674787D 31 M 11 severe 0.457 2634721.19 23.3 CM0106 1 2 2 2 0 2 2 Hosp in
107 384257F 5 F 11 severe 0.372 102.56 38.6 CM0137 1 3 1 2 0 2 2 Hosp in
108 804789D 27 M 12 severe 2.296 22263.805 30.3 CM0146 1 3 1 3 0 2 2 Hosp in
109 252560F 6 M 14 severe 0.186 18031.3625 30.8 CM0155 1 3 2 3 1 2 2 Hosp in
110 180514F 12 M 13 severe 0.353 97576.465 28.2 CM0166 1 3 1 3 1 2 2 Hosp in
111 394177F 11 M 13 severe 0.332 47784.78 32.7 CM0167 1 2 2 3 1 2 2 Hosp in
112 394551F 11 F 12 severe 0.646 269915.2375 26.7 CM0171 1 3 3 3 0 0 2 Hosp in
113 401189F 14 F 15 severe 0.692 1733.94 33.3 CM0176 1 3 3 3 1 2 2 Hosp in
114 415231F 12 F 13 severe 0.382 28891.856 28.9 CM0199 1 3 2 2 0 3 2 Hosp in
115 417148F 17 M 13 severe 0.511 39593.162 28.5 CM0200 1 3 2 3 0 2 2 Hosp in
116 942769D 21 M 15 severe 0.712 985712 26.8 CM0207 2 3 3 3 0 2 2 Hosp in
117 170372F 9 M 13 severe 1.706 202375.2125 28.3 CM0211 1 3 2 3 0 2 2 Hosp in
118 434162D 46 M 14 severe 2.248 17235.407 32.6 CM0225 1 3 2 3 1 2 2 Hosp in
119 439091F 8 F 14 severe 0.16 637.20898 36.4 CM0227 1 3 3 3 0 2 2 Hosp in
120 992176D 7 M 11 severe 0.164 42964.98 32.6 CM0018 1 3 2 3 1 0 1 Hosp out
121 307606F 9 M 11 severe 1.115 124637.1 26 CM0287 1 3 1 3 2 0 1 Hosp out
122 367389F 11 F 15 severe 1.803 116845.68 27.8 CM0105 3 3 2 2 1 2 2 Hosp in
Hosp in - Inpatient Hosp out - Out patient Comm - Community
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